r Registered for transmission by post as a magazine. TRANSACTIONS AND Oi ^ PEOCEEDINGS A OF THE NEW ZEALAND INSTITUTE FOE THE YEAR 1917 <"CV "''a»»- VOL. L (New Issue) EDITED AND PUBLISHED UNDER THE AUTHORITY OF THE BOARD OF GOVERNORS OF THE INSTITUTE ISSUED 15th JULY, 1918 P'tllhtgton, fl.&. MARCUS F. MARKS, GOVERNMENT PRINTING OFFICE William Wesley a* -. Son, 28 Essex Street, Strand, London W.C. NEW ZEALAND INSTITUTE. NOTICE TO MEMBERS. The publications of the New Zealand Institute consist of — 1. Transactions, a yearly volume of scientific papers read before the local Institutes. This volume is of royal-octavo size. 2. Proceedings, containing reports of the meetings of the Board of Governors of the New Zealand Institute and of the local Institutes, abstracts of papers read before them and of papers dealing with New Zealand scientific matters and published else- where, list of members, &c. The Proceedings are of the same size as the Transactions, and are bound up with the yearly volume of Transactions supplied to members. 3. Bulletins. Under the title of "Bulletins" the Board of Governors hopes to be able to issue from time to time im- portant papers which for any reason it may not be pos- sible to include in the yearly volume of the Transactions. The bulletins are of the same size and style as the Transactions, but appear at irregular intervals, and each bulletin is com- plete in itself and separately paged. The bulletins are not issued free to members, but may be obtained by them at a reduction on the published price. Library Privileges of Members. — Upon application by any member to the Librarian of the New Zealand Institute or of any of the affiliated Societies such works as he desires to consult which are in those libraries will be forwarded to him, subject to the rules under which they are issued by the Institute or the Societies. The borrower will be required to pay for the carriage of the books. For a list of the serial publications received by the Library of the New Zealand Institute during 1917 see p. 381. MEMORANDUM FOR AUTHORS OF PAPERS. 1. All papers must be typewritten, unless special permission to send in written papers has been granted by the Editor for the time being. 2. The author should read over and correct the copy before sending it to the Secretary of the society before which it was read. 3. A badly arranged or carelessly composed paper will be sent back to the author for amendment. It is not the duty of an editor to amend either bad arrangement or defective composition. 4. In regard to underlining of words, it is advisable, as a rule, to underline only specific or generic names, titles of books and periodicals, and foreign words. 5. In regard to specific names, the International Rules of Zoological Nomenclature and the International Rules for Botanical Nomenclature must be adhered to. 6. Titles of papers should give a clear indication of the scope of the paper, and such indefinite titles as, e.g., " Additions to the New Zealand Fauna " should be avoided. 7. Papers should be as concise as possible. 8. Photographs intended for reproduction should be the best pro- curable prints, unmounted and sent flat. 9. Line Drawings. — Drawings and diagrams may be executed in line or wash. If drawn in line — i.e., with pen and ink — the best results are to be obtained only from good, firm, black lines, using such an ink as Higgin's liquid India ink, or a freshly mixed Chinese ink of good quality, drawn on a smooth surface, such as Bristol board. Thin, scratchy, or faint lines must be avoided. Bold work, drawn to about twice the size (linear) of the plate, will give the best results. Tints or washes may not be used on line drawings, the object being to get the greatest contrast from a densely black line (which may be fine if required), drawn on a smooth, white surface. 10. Wash Drawings. — If drawing in wash is preferred, the washes should be made in such water-colour as lamp-black, ivory black, or India ink. These reproduce better than neutral tint, which inclines too much to blue in its light tones. High lights are better left free from colour, although they may be stopped out with Chinese white. As in line drawings, a fine surface should be used (the grain of most drawing- papers reproduces in the print with bad effect), and well-modelled contrasted work will give satisfactory results. 11. Size of Draivings. — The printed plate will not exceed 7Jin. by 4^ in., and drawings for plates may be to this size, or preferably a multiple thereof, maintaining the same proportion of height to width of plate. When a number of drawings are to appear on one plate they should be neatly arranged, and if numbered or lettered in soft pencil the printer will mark them permanently before reproduction. In plates of wash iv Memorandum for Authors of Papers. drawings, all the subjects comprising one plate should be grouped on the same sheet of paper or cardboard, as any joining-up shows in the print. Text figures should be drawn for reduction to a width not exceeding 4-J- in. If there are a number of small text figures they should be drawn all for the same reduction, so that they may be arranged in groups. 12. Maps. — A small outline map of New Zealand will shortly be obtain- able at a low price from the Lands and Survey Department, Wellington, upon which details of distribution, &c, can be filled in according to the instructions given above for line drawings. 13. Citation. — Eeferences may be placed in a list at the end of an article or arranged as footnotes. The former method is preferable in long papers. In the list references are best arranged alphabetically, reference in the text being made by writing after the author's name, as it occurs the year of publication of the work, adding, if necessary, a page number and enclosing these in parentheses, thus : " Benham (1915, p. 176).' Example of forms of citation for alphabetical list : — Benham, W. B., 1915. Oligochaeta from the Kermadec Islands, Trans. N.Z, Inst., vol. 47, pp. 174-85. Park, J., 1910. The Oeology of New Zealand, Christchurch, Whitcombe and Tombs. When references are not in alphabetical order the initials of the author should precede the surname, and the year of publication should be placed at the end. 14. In accordance with a resolution of the Board of Governors, authors are warned that previous publication of a paper may militate against its acceptance for the Transactions. 15. In ordinary cases twenty-five copies of each paper are supplied gratis to the author, and in cases approved of by the Publication Com- mittee fifty copies may be supplied without charge. Additional copies may be obtained at cost price. TEANSACTIONS AND PROCEEDINGS OF THE NEW ZEALAND INSTITUTE FOR THE YEAR 1917 VOL. L (New Issue) EDITED AND PUBLISHED UNDER THE AUTHORITY OF THE BOARD OF GOVERNORS OF THE INSTITUTE ISSUED 15TH JULY, 1918 aHdltngfon, $.%. MARCUS F. MARKS, GOVERNMENT PRINTING OFFICE William Wesley and Son, 28 Essex Street, Stband, London W.C. ERRATA. Page 64, line 5 : For Hypolepsis read Hypolepis. Plate VI, fig. 1 : This figure should be inverted. ALEXANDER MCKAY. [ Frontispiece. OBITUARY. ALEXANDER McKAY. Alexander McKay was born at Carsphairn, in Kirkcudbrightshire, Scot- land, in 1842, and was educated as part-time scholar at the village school. He came to New Zealand in 1863, landing at the Bluff from the ship " Helenslee," and for some time he followed the occupation of a gold-miner, both in Otago and at Wakamarino, after which he went to Australia and worked on the New South Wales and Queensland diggings. In 1866 he returned to New Zealand, and for the next four years was engaged in exploring and prospecting the south-west part of the Mackenzie country, conducting his explorations alone and at all seasons of the year. It was during this period that he first became acquainted with Dr. (afterwards Sir Julius) von Haast, then Provincial Geologist for Canterbury. Later, in 1870, while engaged in prospecting for coal at Ashley Gorge, he again met Dr. von Haast, who engaged him as an assistant in prosecuting some geological surveys which he was carrying out for the New Zealand Govern- ment. After exploring the central mountain regions of Canterbury and the Shag Point coalfield the party returned to Christchurch, and Mr. McKay was further employed to collect from the saurian beds of the Waipara Eiver, North Canterbury, for the Canterbury Museum. In 1872 he carried out the excavation of the " Moa-bone Cave " at Sumner under Dr. Haast's directions. Towards the end of that year, Dr. (later Sir James) Hector, noting the fine saurian collections in the Canterbury Museum, engaged Mr. McKay to make a collection of similar remains from Amuri Bluff for the Colonial Museum and Geological Survey. On the conclusion of this work, in March, 1873, Mr. McKay came to Wellington, and shortly afterwards was appointed a permanent officer in the Geological Survey, remaining in this employment until the suspension of the Survey in 1893. After that date he held the appointment of Mining Geologist to the Mines Department, and subsequently of Government Geologist, until his retire- ment from the Public Service in 1906. He died at Kelburn on the 8th July, 1917. The geological work carried out by the Survey under Sir James Hector did not include much mapping or detailed field-work, but consisted chiefly of geological reconnaissance and exploration of unknown localities, together with reports on individual mines or small mining districts. Mr. McKay was employed at first largely in fossil-collecting ; but at a later date, as his colleagues Hutton, Cox, and Park dropped out of the Survey, the greater part of the exploration fell to his share. As a fossil-collector he had a keen eye, but he had rather too high an estimation of the power of a palaeontologist to reconstruct a whole specimen from fragments, and in consequence a considerable proportion of his collections are now being found to be of doubtful utility. It was unfortunate that his collections were not examined and described at once, for with his undoubtedly great aptitude for collecting, and his memory for species, he would have been quick to acquire that special knowledge which is essential to the finest work. His collections were apparently looked over by Sir James Hector, viii Obituary. and a few selected specimens were displayed in the Colonial Museum under their generic names, but the great bulk were stored away and have only recently been partially re-examined. Over 120,000 fossils were acquired by the Geological Survey under Sir James Hector, and of these a considerable majority were collected by Mr. McKay. This tangible result was considered by him his greatest achievement, but it is easily outweighed by his contributions to the field and structural geology of New Zealand. During his geological explorations Mr. McKay covered almost the whole area of New Zealand, and in accordance with the practice then in vogue he prepared reports on all his travels. These papers, published in the Reports of Geological Explorations, still form the only source of information for many districts in New Zealand. In his later years he resumed many of his earlier observations in papers dealing with larger districts, such as , Central Otago, Marlborough, and the West Coast. As a writer he was not always lucid, and seldom graceful in style ; indeed, his earlier papers show that writing must have been a great labour to him. He was under the further disadvantage of not being able to give a simple descriptive account of what he observed, but of having to interpret it in terms of the official classification adopted by the Survey. Nevertheless he had the merit not to suppress any discordant observations, and it is easy for one familiar with the classification adopted to obtain from the reports a clear enough account of the geological sequence he observed. As a field geologist he was a reliable worker, and in districts regarding which controversies have arisen his account has generally stood the test of time. During the last few years of the old Geological Survey, and subse- quently during his employment by the Mines Department, Mr. McKay broke fresh ground in the domain of structural geology. In 1884-85 he traversed the Middle Clarence Valley, and in 1888-89 the Awatere Valley, in each of which there are long strips of Notocene rocks resting on one side of the valley unconformably on the older rocks, and bounded by long fault-lines on the other. On each side the old rocks rise into mountains of 6,000 ft. to 9,000 ft. The presence, in the Notocene series, of the Amuri limestone, a fine-grained chalky limestone containing little or no terrigenous sediment, led Mr. McKay to conclude that at the time of its formation the Kaikoura Mountains, as such, were not in existence. Since the Notocene series is structurally involved in the mountains, he concluded that the latter originated at a comparatively recent (post-Miocene) date. His subsequent work was devoted mainly to the extension of this theory of mountain-building by block-faulting (although he did not actually use these terms) throughout the rest of New Zealand, and notably in Central Otago. Although this work received little attention at the time, it is now accepted as substantially correct by the majority of New Zealand geologists, and it is greatly to Mr. McKay's credit that he originated the idea independently of any influence from other countries. In his later years he devoted much attention to photography, and was very successful in obtaining photomicrographs of igneous rocks, and also long-distance views of the Tararua Mountains from his home in Kelburn. J. A. T. UJ CONTENTS. BOTANY. Art. I. The Prothallus and Young Plant of Tmesipteris. By the Rev. pages J. E. Holloway, D.Sc. . . . . . . . . . . 1-44 IV. A New Species of Hypolepis. By H. Carse . . . . . . 64 XIII. Notes of a Botanical Visit to Hollyford Valley and Martin's Bay, with a List of Indigenous Plants. By D. L. Poppelwell and W. A. Thomson . . . . . . . . . . 146-154 XIV. Notes of a Botanical Visit to Bunker's Island (Stewart Island). By D. L. Poppelwell .. .. .. .. .. 154-157 XV. Notes of a Botanical Visit to Coll or Bench Island (Stewart Island). By D. L. Poppelwell . . . . . . . . . . 158-159 XVII. Notes on New Zealand Floristic Botany, including Descriptions of New Species, &c. (No. 3). By L. Cockayne, Ph.D., F.L.S., F.R.S. .. .. •• •• •• •• 161-191 XXI. On the Distribution of Senecio saxifragoides Hook, f., and its Relation to Senecio lagopus Raoul. By A. Wall, M.A. . . 198-206 XXII. Descriptions of New Native Flowering-plants. By D. Petrie, M.A., Ph.D. .. .. .. .. .. .. 207-211 XXV. Notes on the Autecology of certain Plants of the Peridotite Belt, Nelson: Part I — Structure of some of the Plants (No. 1). By M. Winifred Betts, M.Sc. . . . . . . . . 230-243 GEOLOGY. Art. V. The Stratigraphical Relationship of the Weka Pass Stone and the Amuri Limestone. By R. Speight, M.Sc. F.G.S., and L. J. Wild, M.A., B.Sc, F.G.S. . . . . . . . . 65-93 VI. Structural and Glacial Features of the Hurunui Valley. By R. Speight, M.Sc, F.G.S. . . . . . . . . . . 93-105 VII. The Volcanic Rocks of Oamaru, with Special Reference to their Position in the Stratigraphical Series. By G. H. Uttley, M.A., M.Sc, F.G.S. . . . . . . . . . . 106-117 VIII. Geology of the Oamaru-Papakaio District. Bv G. H. Uttley, M.A., M.Sc, F.G.S. .. .. .. .. .. 118-124 XVI. On the Age of the Alpine Chain of Western Otago. By James Park, F.G.S. . . . . . . . . . . . . 160 XX. On the Age of the Waikouaiti Sandstone, Otago, New Zealand. By J. Allan Thomson, M.A., D.Sc, F.G.S. . . . . . . 196-197 XXIII. The Geomorphology of the Coastal District of South-western Wellington. By C. A. Cotton . . . . . . . . 212-222 XXVI. The Succession of Tertiary Beds in the Pareora District, South Canterbury. By M. C. Gudex, M.A., M.Sc. . . . . 244-262 XXVII. The Tertiary Molluscan Fauna of Pakaurangi Point, Kaipara Harbour. By P. Marshall, M.A., D.Sc. . . . . . . 263-278 XXVIII. Notes on the Geology of the Tubuai Islands and of Pitcairn. Bv P. Marshall, M.A., D.Sc. . . . . . . . . . . 278-279 XXIX. A Note on East Coast Earthquakes (N.Z.). 1914-17. By George Hogben, C.M.G., M.A., F.G.S. . . . . . . . . 280-281 32412 ( 'oiitents. ZOOLOGY. Art. III. Revision of the Cirripedia of New Zealand. By L. S. Jennings, pages B.A., M.Sc. . . . . . . . . . . . . 56-63 IX. Descriptions of New Species of Lepidoptera. By Alfred Philpott . . 125-132 X Descriptions of New Zealand Lepidoptera. By E. Meyrick, B.A., F.R.S. .. .. .. .. .. .. 132-134 XI. Notes from Canterbury College Mountain Biological Station, Cass : No. 6— The Insect-life. By F. W. Hilgendorf, D.Sc. .. 135-144 XII. On a Partially White Form of Puffinus griseus. By D. L. Poppel- well . . . . . . . . . . . . . . 144-145 XVIII. A Note on the Young Stages of Astraea heliotropium (Martyn). By Miss M. K. Mestayer . . . . . . . . . . 191-192 XIX. On Mosquito Larvicides. By H. B. Kirk, M.A. . . . . . . 193-196 MISCELLANEOUS. Art. II. The Resistance to the Flow of Water through Pipes. By E. Parry, B.Sc. . . . . . . . . . . . . 45-55 XXIV. New Zealand Ironsands : an Historical Account of an Attempt to Smelt Ironsands at Onehunga in 1883. By J. M. Chambers . . 223-230 XXX. Further Notes on New Zealand Bird-song : Kapiti Island. By Johannes C. Andersen . . . . . . . . . . 282-295 XXXI. Notes on Eels and Eel-weirs (Tuna and Pa-tuna). By T. W. Downes 296-316 XXXII. On certain Tripolar Relations : Part III. Bv E. G. Hogg, M.A., F.R.A.S. . . . . . . . . . . . . 317-322 PROCEEDINGS. Fifteenth Annual Meeting of the Board of Governors Wellington Philosophical Society Auckland Institute Philosophical Institute of Canterbury Otago Institute Hawke's Bay Philosophical Institute Manawatu Philosophical Society Wanganui Philosophical Society 325-342 343-345 346-349 349-350 350-351 352 352-353 353-354 APPENDIX. New Zealand Institute Act and Regulations Hutton Memorial Medal and Research Fund Hector Memorial Research Fund Regulations for^administering the Government Research < J rant Carter Bequest New Zealand Institute — List of Officers, &c. Roll of Members Serial Publications received by the Library of the Institute List of Institutions^ which the Publications of the Institute are~presented Index 357 357-359 359-361 361-362 362 363-366 367-380 381-385 386-391 392 /$?. AR Y LIST OF PLATES. Alexander McKay Frontispiece. FOLLOWS PAGE 2 22 Hollow ay, J. E. — Plate I. — Tmesipteris tannensis (lanceolata) Plate II. — Longitudinal section, prothallus of Tmesipteris Plate III. — Longitudinal section, point of attachment of young plant of Tmesipteris to the prothallus . . . . . . . . -2 Speight, R. — Plate IV. — Contact of Amuri limestone and Weka Pass stone, showing nodules of phosphatized Amuri limestone, on roadside, Weka Pass . . . . . . . . . • . . 74 Plate V.— Contact of Amuri limestone with Weka Pass stone on escarpment east of viaduct, Weka Pass . . . . . . . . 74 Plate VI.— Fig. 1. Contact of Amuri limestone with greensand layer containing phosphatic nodules, Port Robinson . . . . . . 82 Fig. 2. Nodular layer in Amuri limestone, south side of Amuri Bluff . . 82 Plate VII.— Fig. 1. Nodular layer in Amuri limestone, Maori village, Kaikoura Peninsula . . . . . . . . • • • - 82 Fig. 2. Nodular layer in Amuri limestone, Atiu Point, Kaikoura Peninsula . . . . . . . . . . • • 82 Park, J. — Plate VIIL— Bob's Cove, Lake Wakatipu, showing warping of the Tertiary beds .. .. .. •- .. ..160 Cockayne, L. — Plate IX. — Leptospermum scoparium Leonard Wilson . . . . . . 178 Plate X. — Flowering branch of Leptospermum scoparium Leonard Wilson . . 178 Wall, A. — Plate XL — Relief map of Banks Peninsula . . . . . . . . 198 Plate XII. — Young plant of Senecio saxifragoides . . . . . . 202 Plate XIII. — Plants of Senecio lagopus . . . . . . . ■ 202 Cotton, C. A. — Plate XIV.- — General view of southern end of coastal lowland . . . . 218 Plate XV — Fig. 1. Fan with cliffed seaward margin, north of Paekakariki . . 218 Fig. 2. Dissected bench of Otaki sandstone near Shannon . . . . 218 Gudex, M. C. — Plate XVI — Fig. 1. View of the fluted limestone at Otaio Gorge . . . . . . 250 Fig. 2. Solution-pits in the limestone of Holme Station . . . . 250 Plate XVII.— Fig. 1. Road-cutting on Squire's Farm. The columnar structure of the loess is seen . . . . . . . . . . [ 250 Fig. 2. The upper part of Little River Valley, viewed from Squire's Farm 250 Xll List of Plates. Maeshall, P. — Plate XVIIL- Plate XIX.- Plate XX.- Plate XXI.- -Fossils from Pakaurangi Point -Fossils from Pakaurangi Point -Fossils from Pakaurangi Point -Fossils from Pakaurangi Point Plate XXII. — Fossils from Pakaurangi Point FOLLOWS PAGE 264 264 270 270 272 Downes, T. W .— Plate XXIII. — Small pa-tuna at Ngutuwera, Moumahaki River Plate XXIV. — Making a poha, Waitotara Plate XXV.— Fig. 1. Pa-tuna, or eel-weir, at Kauwae-roa, Whanganui River, looking down -stream Fig. 2. Pa-tuna at Kauwae-roa, Whanganui River, looking up-stream. . Plate XXVI. — Pa-tuna on Te Aute-mutu Rapid, Whanganui River Plate XXVIL— Fig. 1. Utu, or lamprey- weir, at Parikino, Whanganui River, looking down stream Fig. 2. Utu, or lamprey-weir, at Parikino, Whanganui River, looking up stream Plate XXVIIL— Figs. 1, 2. Hinaki herehere of different patterns Fig. 3. Korotete Plate XXIX. — Hinaki Plate XXX. — Hinaki Plate XXXI. — Hinaki Plate XXXIL— Hinaki Plate XXXIIL— Hinaki Plate XXXIV.— Hinaki kareao pattern (ripeka) pattern, showing arrangement of ribs pattern (elongated ripeka) pattern (pakipaki or aurara) . . pattern (phable) 310 310 310 310 310 312 312 312 312 312 312 314 314 314 314 TEANSACTIONS. RARY TRANSACTION S OF THE NEW ZEALAND INSTITUTE, 19 17. Art. I. — The Prothallus and Young Plant of Tmesipteris. By the Rev. J. E. Hollo way, D.Sc. [Received by Editors, 31st December, 1917 ; issued separately, 24th May, 1918.] Plates I-III. It has been mainly, perhaps, owing to the fact that the various members of the Psilotaceae are confined to tropical and subtropical regions, and to the temperate countries of the Southern Hemisphere, that our knowledge of the gametophyte and of the embryogeny of the sporophyte of this interesting group of plants has increased so slowly. This order has been the last to yield information with regard to the early stages in the life- history of its members, and so to furnish evidence which may help us to form reasonable theories concerning its genetic relationships. The genus Tmesipteris, for example, is confined to Australia, New Zealand, and certain Pacific islands, and hence has remained for the most part beyond the reach of European and American botanists. With regard to not a few of the chief pteridophytic groups, not only has the number of those who have searched for the prothallus been limited, but the search itself has been rendered difficult on account of the fact that the gametophyte is often subterranean, and also that although the adult plants are not as a rule rare in their occurrence, yet their abundance in any particular locality is often due largely to their powers of vegetative reproduction, for the germination of the spores seems only to take place in localities where the conditions are peculiarly favourable, and where also the prothallus and young plant will remain quite undisturbed during the protracted period of their development. However, it seems to be evident from the writings of most of those who have given an account of the details of their search for pteridophytic prothalli that when once one can learn from experience in the field to recognize the localities favourable to the development of the particular kind of prothallus searched for there is no obstacle other than the necessity 1— Trans. 2 Transactions. for patience in dissecting to hinder its being collected in comparative abundance.* There is no doubt that the wet temperate climate of that part of New Zealand subject to the excessive western rainfall is especially favour- able to pteridophytic growth and to the sexual reproduction of the plants. In the present paper I propose to give an account of my search for and discovery of the prothalli and young plants of Tmesipteris in the neighbourhood of Hokitika, in the Province of Westland, New Zealand, and to describe the form, structure, and development of the prothallus and sexual organs and of the young plant, and also to trace some of the early stages in the development of the embryo. Two writers have pub- lished certain results obtained by them in their search for the gametophyte of the Psilotaceae. Lang (1904) has given a description of a single pro- thallus which he has provisionally referred to Psilotum. This prothallus is certainly a puzzle, for on the one hand the finding-place strongly suggests that it belongs to Psilotum, but on the other its form and structure differ very widely from what I propose to describe for Tmesi- pteris, and from what Professor A. A. Lawson, of Sydney University, has already described. Lawson (1917a) gives a preliminary account of the prothallus of Tmesipteris based upon several specimens obtained by him from different localities in eastern Australia. This account was pub- lished early in 1917, but came into my hands only at the end of the year, when my own paper was almost completed. No reference to it. therefore, will be found in the body of the present paper, but in the concluding section I have compared in detail my own results with his, and noted our points of agreement or otherwise. There is a considerable literature dealing with the anatomy and morphology of the adult plant in the Psilotaceae. The more recent of those writings, such as those of Scott (1909), Bower (1908), Seward (1910), Thomas (1902), Boodle (1904), Ford (1904), and Sykes (1908), have brought together a weighty body of evidence for relating the Psilotaceae with the fossil Sphenophyllales. In my comparative remarks I have endeavoured to consider the results obtained from the study of the prothallus and young plant of Tmesipteris with regard to the systematic position to be assigned to Tmesipteris and Psilotum. As on other occasions, I desire to acknowledge the special debt of gratitude I am under to Dr. L. Cockayne, F.R.S., for his constant encouragement and advice, and also to Professor C. Chilton, M.A., D.Sc, for his kindness in giving me free access to the Botanical Laboratory at Canterbury College. *The following may be cited in this connection: H. Bruchmann, Uber die Pro- thallien und die Keimpflanzen mehrerer europiiischer Lycopodien, pp. 4 and 5, 1898 ; D. H. Campbell, The Euspomngiatae (the adult gametophyte of Ophioglossum molucca num and O. pendulum), pp. 11 and 13, 1911 ; M. Treub, "Some Words on the Life-history of Lycopods" (tropical species), Ann. o/ Bot., vol. 1, pp. 119-23, 1887; J. E. Holloway, ••Studies in the New Zealand Species of the Genus Lycopodium, Part I," Trans. N.Z. Inst., vol. 48, pp. 259-63, 1916. In the last- mentioned paper I described the discovery of three species of Lycopodium prothalli of the L. c< rn u u m type, one epiphytic species of the L. Phlegmaria type, and three subterranean species of the L. complanatum and L. clavatum types, the three latter being found in abundance. Since writing this paper I have found the prothalli oi the three epiphytic varieties of Lycopodium which occur in New Zealand, in the case of two of them in great abundance, and have also continued to come across sporeling plants and prothalli of the three subterranean species in many different localities, and in large numbers. Trans. N.Z. Inst., Vol. L. Plate I. 60 O Oh 3 "to hH -If? & cu GO aT CD la a 60 a o s a 60 C O 60 00 5. 5V lace p. 3.1 3 Holloway. — The Protlvallus and Young Plant of Tmesipteris. Occurrence and Habit. Tmesipteris occurs commonly throughout New Zealand as an epiphyte on the stems of tree-ferns and other forest-trees. The much-branched brown rhizome penetrates through the mass of aerial rootlets which densely clothes the stem of the tree-fern, and especially is to be found under- neath the decurrent stipites of its fronds. Certain of the rhizome- branches turn upwards, and emerge as green aerial shoots, bearing scattered scale leaves below and above the full-sized leaves of charac- teristic form and the sporophylls. There is a certain amount of variation noticeable in the habit and general form of the plant, which is probably to be put in connection with the nature of the surface on which it grows. However, it must be noted that some writers have recognized distinct varieties. For example, when growing on certain species of the tree-fern Cyathea the whole plant is gene- rally somewhat stunted in size, the rhizome being more scantily branched and the aerial shoots short and semi-erect. In these cases the surface of the tree-fern stem consists solely of the mat of black brittle aerial rootlets, the stipites of the fronds not reaching down the stem much below its crown, and consequently there being only the dense tough mat, of greater or lesser thickness, of the interlaced rootlets in which the Tmesipteris plants can grow. My experience has been the same probably as that of others who have tried to dissect out the plants from such intractable material. It is almost impossible to get the plant with all its various branchlets complete, and one gives up in despair the search for the young plants or for the prothallus. In those parts of New Zealand, however, especially in the botanical districts, as defined by L. Cockayne,* which lie for the most part west of the Southern Alps, together with that ecologist's South Otago and Stewart Districts, where the average rainfall is very heavy, there is an extremely rich growth of Pteridophytes, and Tmesipteris occurs abundantly on the tree-fern Dicksonia squarrosa and on moss- or humus-covered forest-trees, and also in the heaps of humus which lie on the ground at the bases of the trees. Here the size and habit of the plant are markedly different from those described above. The penetrating rhizomes may be as much as 2 ft. or 3 ft., or even more, in total length, and are for the most part extensively branched ; also, it is an easier matter to dissect out a plant entire from such a substratum. The aerial branches arising from a single plant are fairly numerous, and droop down 2 ft., 3 ft., and 4 ft. in length, the branches of groups of plants hanging like a fringe from some tree-branch or fallen tree-stem. In Plate I is shown a single plant with a much-branched rhizome and three aerial stems, the latter showing fertile regions. I have found in the neighbourhood of Hokitika, Westland, in the low- lying forest which borders the sea-front, both young and mature plants of Tmesipteris growing on the stems of Dicksonia squarrosa in great abundance. On this particular tree-fern the frond-stipites run down the stem for some distance before they enter its surface, and hence in young individuals the greater part of the stem, and in older plants the upper portion, is covered with the adhering bases of the fronds. The young plants of Tmesipteris occur both immediately underlying the stipites and in the ridges of aerial rootlets which project outwards between them. During the month of September, 1917, I obtained several lengths of tree- * Trans. N.Z. Inst., vcl. 49, p. 65, 1917. 1* 4 Transactions. fern stems which showed the presence of abundant young plants of Tmesipteris, and took them home for dissection. Between twenty and thirty prothalli were discovered on this occasion in all stages of develop- ment (except, of course, the very youngest), some of these prothalli bearing young plants in various stages of growth. During the following two months many other prothalli were obtained in the same way, the total number to date being between sixty and seventy, as well as many isolated prothallial plantlets, some of the latter being complete and others broken in process of dissection. By reason of their brown colour and large size, the prothalli and the rhizomes of the young plants are clearly to be seen amidst the tangle of black aerial tree-fern rootlets. There is not much humus present, but the rhizoids of the prothalli and plantlets are closely intermixed with ramenta from the tree-fern. Prothalli and plantlets also of Lycopodium Billardieri var. gracile were found in abundance on these tree-ferns, and also the prothalli of various ferns and several liverworts. The spores of Tmesipteris germinate best on those parts of the tree-fern stems where the surface, owing to the presence of the frond-stipites, is more loose and open. The young plants, once established, will develop, and their rhizomes ramify in all directions, even after the bases of the fronds have completely fallen away and their places have been filled up by the mat of aerial rootlets ; but the younger plantlets will only be found higher up the stem. It was noticed that in the groves of Dicksonia squarrosa in this particular locality many young tree-ferns of from 6 ft. to 8 ft. in height bore young developing plantlets of Tmesipteris, but that it was only on still taller stems that the mature plants were to be seen, whilst from those of 15 ft. or more in height the plants had generally disappeared altogether from the lower portions of the stem and were only to be found on the upper half. It would seem that Tmesipteris prefers a fairly loose substratum both for the germination of its spores and also for the full development of the plants. That this is so becomes apparent when one observes the conditions under which it flourishes on Stewart Island and on those parts of the mainland {e.g., Bluff Hill) which face Stewart Island across Foveaux Strait. In these localities Tmesipteris occurs very commonly in the masses of loose humus which are gathered at the bases of forest-trees and tree- ferns, and there the plant often reaches a most luxuriant development. Also, on such large branches and tree-trunks throughout the forest as are covered with humus, and especially on those which lie more or less horizontal, there is frequently a rich growth of the plant. In January, 1915, I made a visit to Stewart Island for the purpose of searching for the young plants and prothalli of Tmesipteris. This botanical district is well known to be exceptionally favourable for the growth of epiphytic ferns and lycopods, on account of its wet climate. There is one locality especially, bordering the shore of Preservation Inlet, near the upper reaches of its south-west arm, where there is a very characteristic and interesting type of forest. This has been described by L. Cockayne in his Report on a Botanical Survey of Stewart Island (Government Printer, Wellington, 1909). Cockayne speaks of this type of forest as " the Yellow-pine (Dacry- dium intermedium) Association." This particular association is confined to wet ground, and the low forest consists mainly of the small pine which gives its name to the association, and of other conifers, as, for example, Dacry- dium biforme, Podocarpus Hallii, and certain other species belonging to these two genera ; while the floor of the forest is covered with curious Holloway. — The Prothallus and Young Plant of Tmesipteris. 5 large globular cushions of mosses and liverworts {e.g., Dicranoloma Bil- lardieri and species of Plagiochila) from 1 ft. to 2 ft. or more in diameter, and with three species of Lycopodium (L. volubile, L. scariosum, and L. varium) growing in wonderful luxuriance. Lycopodium varium here grows in great clumps, which are as much as 6-8 ft. across. Tmesipteris and filmy ferns are also in great abundance — in fact, the general appearance of the vegetation is suggestive of a past age when Gymnosperms and Pteridophytes were dominant rather than Phanerogams. During my visit to Stewart Island I arranged an expedition to spend a few days in this locality, but owing to heavy rains and floods the party was isolated on the sea-coast and nearly met with disaster. However, on the last day I reached the spot, and during an hour's search succeeded in finding several young prothallial plantlets of Tmesipteris growing in thick loose humus on a fallen tree-trunk. There is no doubt that with longer time at his disposal a searcher would find the place a most favourable one for the discovery of both the young plants and the prothalli. It was not till the spring of 1917 that the further discovery was made, in the neighbourhood of Hokitika, of both plantlets and prothalli of Tmesipteris, as recorded above. In the dissection of these specimens from the mass of aerial rootlets on the stems of the tree-ferns a certain amount of patience and care had to be used, for these rootlets are ex- ceedingly tough and are closely intermatted, and both the prothalli and rhizomes of Tmesipteris are very brittle and easily broken. However, by pulling away the stipites of the tree-fern fronds and carefully tearing apart the mass of aerial rootlets the golden-yellow rhizomes and the brown prothalli were easily to be seen (by reason both of their characteristic colour and of their comparatively large size), and, the black aerial rootlets being cut away with dissecting scissors, they were readily obtained. General Form and Structure of the Prothallus. The prothallus-body is cylindrical in form, being radially constructed. It is brown in colour, and is covered with numerous long golden-yellow rhizoids. It never seems to reach the light, and is quite destitute of chlorophyll. The largest specimens found are shown in figs. 5, 6, and 8, being 18 mm. and 13 mm. respectively in total length, and the smallest in figs. 11 and 12, these being from 1 mm. to 2 mm. long. In its un- branched form the prothallus is carrot-shaped, tapering down gradually from a fairly thick head and upper region towards the basal first-formed end, which culminates in a more or less long-drawn-out point (figs. 1, 2, and 11). The first-formed basal region does not show such a marked primary tubercle as is so well known in the case of the prothalli of Lycopodium cernuum or in those of Ophioglossum and Helminthostachys, but there is commonly a succession of gentle swellings from the original point of growth upwards by which the prothallus grows in girth (figs. 1, 2, 11, and 13). The actual head is generally the stoutest region (figs. 12, 13, &c), being sometimes curiously swollen, and the growing apex is bluntly rounded. Sooner or later the head of the prothallus forks dichotomously, and one of the branches so formed may later fork again. In some cases the first branching is postponed till after the prothallus has attained a length of as much as 8-10 mm. (figs. 1, 2), and the result is the carrot form ; more often, however, the first forking takes place comparatively early (fig. 6), and many adult prothalli were found in which one of these Transactions. Fig. Fro. branches had developed into the main prothallus-body, whilst the other had either broken away or persisted towards the base of the first in a state of arrested growth (figs. 4, 5, 6). The forking generally seems to result at first in two equal apices of growth (figs. 1, 2), and hence may be termed dichotomous, and, except in the case of the first branching as just described, which takes place when the prothallus is still comparatively small, the resultant branches become more or less equally developed (figs. 2 and 5). Hence in most adult prothalli found the original simple carrot- shape form had been lost, and the prothallus had become more irregular in appearance, L dp such as is generally the case with epiphytic prothalli. Thus in this respect the prothalli of T mesipteris can be compared with those of the epiphytic species of Lycopodium and Ophioglossum. In a few instances, moreover, such as those illustrated in figs. 6 and 66, a still greater irregularity of form had been brought about through the branching not taking place dicho- tomously. In the former of these two prothalli the forking seems to have been trichotomous. Still another irregularity in the form of adult prothalli is brought about by the equal development of both daughter branches at the first forking of the prothallus, not, as is usually the case, at an angle to one another, but in directions dia- metrically opposite (fig. 7). This is still more pronounced in the case of the large prothallus shown in fig. 8, in which one of the branches resulting from the first forking had forked again, the two branches of this second forking proceeding to develop in opposite directions ].— Complete prothallus, carrot to one another in the same straight line, form, bearing young plant. Thus the branched form of the adult pro- thallus is attained normally by the dichoto- mous forking of the apex, but I observed also a few instances in which short undeveloped branches had arisen apparently laterally. However, even in the most irregularly shaped adult individuals the manner of growth can always be easily traced, for even if the original long-drawn- out point be not preserved, yet the oldest region can always be dis- tinguished from the rest of the prothallus by its darker brown or even almost black colour. On some of the prothalli a large cup-shaped prominence with an obviously lacerated rim was to be seen (figs. 4 ard 73). This is where a young plantlet had been broken away, the cup-shaped prominence having been formed by the localized outward growth of the prothallial tissues around the embryo and their final rupture by the developing plantlet. Such a point of attachment of the plant to its parent prothallus , and showing original end intact. X 10. 1a. — Original end of prothallus shown in fig. 1. X 24. Hollow at. — The Prothallus and Young Plant of Tmesipteris. may be seen sometimes in the lower regions of the latter (fig. 5), indicating that the growth of the prothallus is by no means arrested by the develop- ment on it of a plant, but may go on after the latter has attained a considerable size or has even become detached from the prothallus. When first seen amongst the tangle of black aerial rootlets of the tree- fern stem the prothalli may easily be mistaken for broken portions of the rhizome of young plants or for very young complete isolated plantlets, and vice versa. Both the prothalli and the rhizomes are brown in colour, and both are covered fairly thickly with the long yellow-brown rhizoids Fig. 2. — Complete prothallus, carrot form, commencing to fork, bearing young plant, x 9. Fig. 3. — Prothallus, carrot form, original end broken off, showing swollen head. X 12. Fig. 4. — Prothallus, branched, one branch broken off, shows original end intact, also point of attachment of young plant, x 12. Fig. 4a. — Original end of prothallus shown in fig. 4. x 36. or with the characteristic small brown circles formed by the persisting bases of broken-ofi rhizoids. The similarity holds also with regard to their growing apices, which are always somewhat swollen and are clear and whitish in appearance and show rhizoids only in their earlier stages of development. Each object dissected out has generally to be separately cleaned and examined under a low power of the microscope before its nature can be definitely determined. This is especially so in the case of the branched prothalli, whereas the carrot - shaped individuals are more easily recognized. However, generally speaking, the colour of the 8 Transactions. prothallus is more opaquely brown than that of the rhizome, the latter appearing a clearer golden brown, with its surface cells outlined with great distinctness, this difference in appearance being due possibly to the denser fungal element in the interior tissues of the prothallus. The older basal regions of the pro- th alii are often darkly brown in Fig, 5. — Complete branched pro- 3 thallus of large size, bearing^] young plant which "shows \ both rhizome and aeri stem, x 3. Si WF" p colour or even blackish, owing not so much to any withering- away of the tissues as to the presence of the mycorhiza in this region in the cells immediately underlying the Q. epidermis, and, in the oldest regions of all, in the epidermal cells also, as well as in those more centrally situated. The prothallus in trans verse section is round in out line (figs. 16 and 17), this being so throughout its length, so that its construction is consistently radial. Its growth in length is referable to the activity of a single cell (figs. 20 and 21), such as is the case also with the cylindrical pro- thalli of the Ophiogk ssaceae. A transverse section through the main Fig. 6. — Complete branched prothallus of large size, one main branch showing further irregular branching, x 10. Hollow ay. — The Prothallus and Young Plant of Tmesipteris. body of the prothallus shows its tissues to be composed of cells of uniform size and shape, there being do differentiation of central long conducting cells or of fungal zones such as are so well known in most of the types of Lycopodium prothalli. The dense fungal coils occupy uniformly practically all the cells in the central region, the epidermis and a zone three or four cells in width immediately underlying it alone being free from these coils. In the limbs of the larger prothalli this subepidermal layer sometimes con- tains much starch. Moreover, meristematic activity sometimes shows itself in these cells (fig. 19), though whether in connection with the storage of starch or with the development of the sexual organs is not quite clear. The mycorhiza extends uniformly right up through the length of the prothallus to close behind the actual apex, keeping pace with the forward growth of the latter. A series of transverse sections behind a growing apex shows that at its uppermost limit the mycorhiza occupies only a narrow central Fig. 7. — Complete, branched prothallus, in which the branches are not inclined to each other at angle but in opposite directions. X 10. Fig. 8. — Branched prothallus, one branch broken ; the other has branched again in the manner described for fig. 7. X 5. core of cells, which gradually tapers off upwards, and that in these cells the hvphae are more scantily developed. The fungal hyphae in these growing regions of the prothallus are wholly absent from the cells which surround the central core, this fact showing that when once the mycorhiza has entered the prothallus in its earliest stages of development no further infection is needed, but that the fungus extends upwards in a uniform manner, keeping pace with the growth of the prothallus. The clear white colour of the actual apex is, of course, due to the absence of the fungus from its cells. In the older parts of the prothallus hyphae can often be distinguished penetrating through the length of rhizoids and across the outer layers of cortical cells, but it is probable (as is also considered to be the case in other pteridophytic prothalli which are infected with a mycorhiza) that this signifies no organic connection between the fungal 10 Transactions. hvphae within the prothallus and those in the surrounding humus. A great outward growth of hyphae was noticed from the surface of teased-up portions of young rhizomes which had been kept for some days in water in a watch-glass, and many of the threads showed what seemed to be single round spores at regular distances along their length. At its uppermost limit the hyphae of the mycorhiza in the interior cells of the prothallus are scantily developed, but farther back the coils become more dense. Throughout the greater part of the prothallus the fungal contents of each cell show as a dense globular mass, in which the identity of the hyphal Fig. 9. — Old withered prothallus. carrot form, attached to plantlet which is broken above and below. X 3. Fin. 10. — Old withered branched prothallus, attached to plantlet from which aerial stem is broken off. X 2. FlG. 11. — Very young complete prothallus, showing original end intact and antheridia on its head. > 4~>. threads can no longer be traced. These globular contents of the cells present a very characteristic feature both in the prothallus and young rhizome. (See Plate II.) Not a few well-grown prothalli showed the original point of growth almost intact, and the remains of the first-formed filament, which arises, presumably, immediately from the spore, could be very clearly seen (figs. 1a, 4a, 11, 12, and 13). In two instances — namely, the very young prothallus shown in fig. 11 and the much older one in fig. 1a — there was present at the extremity of the basal end a short filament of cells, two or three in length, which in the former case was seen to be incomplete, Holloway. — Tin Prothallus and Young Plant of Tmesipteris. 11 but in the latter was apparently quite complete. The prothallus shown in fig. 4a tapered off at the basal end to a single cell, which showed no sign of original farther extension such as would compare with the longer filament in figs. 1a and 11. But the single cell in which the basal point of most of the youngest prothalli found by me terminated did give evidence of having had a farther cellular extension broken away from it, In all these prothalli the terminal basal cells, whether single or in the form of a short linear filament, all contained the same dense masses of the fungal element which are present in the other parts of the prothallus. Thus it would seem that the fungus enters the prothallus im- mediately the spore begins to germinate, unless perhaps we take it that it spreads downwards into the filament subsequent to the infection of the prothallus through the first-formed rhizoids. Probably the delicate original basal filament owes its preserva- tion to the fact of the presence in its cells of these fungal masses, the collapse of the cells being thus prevented. At any rate, the preservation of the actual original point of the prothallus of Tmesipteris in so many indi- viduals, some of which were well grown, is rather remarkable. It would seem, then, though it must be stated that the remains of the originating spore itself have not been seen, that on germination the spore gives rise to a short linear filament of cells, and that this, after from one to three or more single cells have been cut off, proceeds to the formation of a cell-mass. This basal primary tubercle is well preserved in the prothalli shown in figs. 1, 2, 4, 11, 12, and 13, and it will be seen that in most cases it shows no great development. The further stages of growth of the prothallus can be clearly seen from a comparison of the young and the older individuals shown in these figures. The prothallus grows in a succession of gentle swellings, each a little bigger than the last, the increased cell-multiplication which these swellings indicate being due probably to the accumulation of food material at the apex, consequent on the activity of the mycorhiza. In fig. 14 is shown one of the limbs of the large prothallus illustrated in fig. 6 ; serial sections through this limb showed that the cells of the apical region were packed with starch. Thus, as the prothallus grows, its apex becomes more and more bulky, so that the whole prothallus-body acquires the carrot form, until at length, owing probably to the stimulation set up by the presence of abundant Fig. 12. — Very young complete prothallus, showing papillose -like outgrowth of epi- dermal cells. Antheridia on head. X 45. 12 T fa nsact ion s . food, contents in its cells, the head of the prothallus forks and the carrot form gives place to the branched form characteristic of the full-grown individuals. The Distribution of the Sexual Organs. There is no differentiation of the prothallus into vegetative and repro- ductive regions, such as is usual,- for example, in the terrestrial forms of Lycopodium prothalli. The sexual organs are distributed over the sur- face of the whole prothallus-body in large numbers, and often in groups. A transverse section of the limb of a prothallus will often show either antheridia or arcliegonia distributed more or less all around the surface (figs. 16 and 17). The sexual organs are for the most part more inter- mingled than is the case in the branched prothalli of the epiphytic lycopodiums, and correspond in this particular rather to the prothallus of Ophioglossum (Campbell, 1911, p. 10). The young developing sexual organs are to be found immediately behind the growing apex of the prothallus, but also, as is known to be the case in 02Jhioglossum (ibid., p. 29), they frequently arise much farther back from it amongst old organs. As a rule, however, both the antheridia and the archegonia arise immediately behind the growing apices in acropetal succession. In nearly every prothallus I noticed developing antheridia on the growing branches, in some cases the youngest being fairly close behind the actual apex, whilst in others (where possibly the growth in length of the branch was taking place more rapidly) at a greater distance back from it. In only a very few out of the large number of prothalli found by me were groups of young archegonia to be seen close behind the apex. This fact, however, is probably due to chance only, for archegonia always occur in large num- bers on the main prothallus-body, though the tendency to grouping is more to be remarked in the distribu- tion of the archegonia than of the antheridia. It may possibly be that the archegonia arise in an irregular manner on older parts of the pro- thallus more frequently than do the antheridia. In several instances of adult prothalli (figs. 1, 2, and 3) where growth had slackened, old archegonia were present in fairly large numbers close behind the apex. In the very young prothalli shown in figs. 1 1 and 12 it will be seen that the sexual organs begin to develop comparatively early, and that it is the antheridia that are first formed. The basal regions of older prothalli also generally show the presence of old antheridia. In surface appearance the young developing antheridia are seen as colourless hemispherical pro- turberances (figs. 6, 12, 13, &c). This is generally one of the most Fig. 13. — Young complete prothallus, showing swollen bead, sexual organs, and original end. X 16. l'lii. 13a. — Original end <>f prothallus shown in fig. 13. > 3(1. Holloway. — The Prothallus and Young Plant of Tmesipteris. 13 marked features of the growing head of the prothallus. Developing antheridia in surface view are shown in fig. 14. There is a single opercular cell at the apex of the protuberance, whose walls early become brown in colour, thus defining the cell very clearly. This browning soon extends to the walls and contents of all the outer cells on the free portion of the antheridium. In the ripe antheridium the interior mass of spermatocytes can clearly be seen in surface view. The antheridium is emptied through the breaking-down of the opercular cell, the aperture thus formed becoming enlarged in still older individuals by the breaking- away also of those cells which adjoin the opercular cell. Thus the cha- racteristic appearance of old antheridia all over the main prothallus-body is that of brown cup-shaped structures projecting from the prothallus- surface (fig. 14, &c). Fig. 14. — One of the large heads of prothallus shown in fig. 6, with antheridia in various views. X 52. Fig. 15. — Small head of a prothallus, showing archegonia in various stages of development, x 66. The young archegonium is first visible in surface view from the division into four of its outej: cell and their arrangement quadrantwise. At first, near the apex of the prothallus, this group of four cells is colourless, but in older organs the cell-wails and the aperture of the neck-canal between them becomes brown in colour, and the archegonia are thus clearly defined in surface view (fig. 15). The neck of the arche- gonium early projects from the surrounding epidermal cells, and is straight rather than curved. Generally speaking, in older parts of the prothallus the neck has broken short off, so that the characteristic appearance of the group of four cells which surround the aperture of the archegonium 14 Transactions. in these eases is that of the lowest tier of neck-cells. In fig. 15 is shown the head of a small limb of a prothallus with archegonia in different stages of development, in surface view. There are not lacking signs of dorsiventralitv in the distribution of the sexual organs, but these are probably unimportant. For example, the old antheridia are sometimes much more numerous along the edges of the prothallus (in the plane in which it naturally lies), and also at the growing apices the young antheridia sometimes occur more numerously towards the edges. This tendency to dorsiventralitv is more apparent still in the fact that in some of the younger prothalli one surface was antb ax. Fig. 16. — Transverse section of limb of prothallus behind growing apex, showing antheridia and archegonia. x 100. noticed to be almost if not entirely free from rhizoids and sexual organs, whilst the opposite surface bore them both. In the young prothallus shown in fig. 12 one surface was quite naked and smooth, but on the other there were a fair number of rhizoids, and the surface was noticeably rough on account of the protruding of the epidermal cells in a papillose manner, and also at the edges were both rhizoids and antheridia to be seen. These indications of dorsiventrality in the distribution of the sexual organs are not, however, always to be observed, and, on the whole, both antheridia and archegonia may be said to be distributed more or less evenly around the surface. Holloway. — The Pro! hull us and Young Plant of Tmesipteris. 15 Development of the Sexual Organs. As has been stated in the preceding section, developing antheridia were commonly seen at the growing apices of the prothalli, but only in a very few prothalli did I find groups of young archegonia. In the older regions of the prothallus, where both antheridia and archegonia not infrequently arise singly amongst old organs, I did not find any in the earliest stages of development, though many of both kinds in later stages were to be seen. The fact that the apex of the prothallus is generally very broad militated somewhat against the study of the young developing organs, for transverse sections in this curving region of the prothallus-head cut ar. Fig. 17. — Transverse section of main limb of prothallus in older region, showing portions of old sexual organs, also two fertilized archegonia. X 100. them often obliquely. However, I was able to obtain a fairly good series of both, although certain points must be left for a more complete study. Perhaps it would not be out of place for me to describe at this juncture the methods adopted for the preparation of my material for microscopic investigation. After the preliminary study and drawing of each prothallus as it was dissected out of the tree-fern humus, it was killed and fixed by immersing for twenty-four hours in a solution of chromo-acetic acid, the formula for which is that given by Chamberlain on p. 21 of his Methods in Plant Histology (3rd ed., 1915). This was found to answer quite satis- factorily so far as the more obvious histology of the prothalli and sexual 16 Transactions. organs was concerned. Some of the material was sectioned by the micro- tome, but I found that it showed a tendency in the older regions to resist infiltration by the paraffin. I was inclined to ascribe this to the very dense nature of the fungal element. The prothalli of Tmesipteris are so firm and large that I decided to hand-cut a number of prepared specimens (having no lack of material) in order to supplement my serial sections with others to as great an extent as possible. I found that, on the whole, the hand-cut sections gave good results, being free from the shrinkage so often associated with the microtome sections. Moreover, they took the stain better. The obvious disadvantage of the hand-cut sections is that they are not kept in Fig. 18. — Portion of main limb of prothallus in tangential longitudinal section, showing archegonia. X 70. Fig. 19. — Portion of main limb of prothallus in transverse section, showing meri- stematic activity underneath the epidermis, x 137. Fig. 20. — Transverse section of apex of prothallus. showing single apical cell. X 137. Fig. 21. — Longitudinal section of apex of slender limb of prothallus, showing single apical cell. X 137. proper sequence. I used throughout Delafield's haematoxylin as a stain, combining it with safranin for the vascular tissues. This haematoxylin was very satisfactory, especially for differentiating the young embryos. However, this method of staining failed to show anything of the process of spermatogenesis. Campbell (1911, p. 28) recommends using the com- bination stain safranin and gentian violet for this purpose, as, indeed, generally for prothallial work. In detecting the youngest stages in the development of the sexual organs one is guided by the fact that they occur in close association with others and also with slightly older organs, and also by the greater size of their Holloway. — The Prothallus and Young Plant of Tmesipteris. 17 nuclei and the deeper staining both of these and of their other cell-contents than is the case in the ordinary vegetative cells. They do not arise so near the actual apex of the prothallus as is the case in the Ophioglossaceae or as I have found in the epiphytic prothalli of Lycopodium Billardieri. Figs. 22-33. — Series showing the development of the antheridium. X 150. Fig. 34. — Mature antheridium, showing opercular cell. X 137. In the development of an antheridium from an epidermal cell the first division wall to be formed is a periclinal one cutting off an outer from an inner cell (figs. 22 to 25). Sometimes the inner of these, and at 18 Transactions. others the outer, is the larger. The mother cell does not at first project beyond the surface of the prothallus, but by the time the first division in it has taken place it has enlarged considerably and has begun to project noticeably. The next division takes place in the outer cell by an anti- clinal wall (figs 24, 25). I have no direct information as to the exact sequence of divisions which takes place in the cover-cell, but it is clear that it gives rise to the whole of the outer free wall of the antheridium, whilst from the inner cell is formed the mass of spermatocytes. From figs. 26 and 28 it would seem that a good deal of segmentation takes place in the inner part of the developing antheridium before the outer wall begins to project at all strongly. I did not observe in my preparations any instances of an antheridium in this stage in transverse section, but it will probably be the case that quadrant and octant divisions are formed in the inner cell, as is known in other Pteridophytes. The free wall of the antheridium is never more than one cell in thickness. The mature antheridium projects very strongly beyond the surface of the prothallus as a hemispherical globular body, the number of cells in the free wall being large. From mature antheridia seen in surface view (fig. 14), it is evi- dent that the division walls in the cover of the antheridium intersect one another more or less at right angles, so that the opercular cell is four- sided. This cell is situated at the apex of the antheridium, and is first to be distinguished in surface view by its walls becoming brown in colour (fig. 14). This browning later extends to the adjacent cell-walls, and, before the antheridium has discharged, both walls and contents of most of the cover-cells in the exposed portion of the antheridium have assumed the same coloration. The interior cells of the antheridium rapidly sub- divide (figs. 29 to 33), so that a large number of spermatocytes is formed, although the number is not so great as in certain of the Ophioglossaceae and in the subterranean types of Lycopodium prothalli. From the adjacent prothallial cells a wall of more or less flat cells is cut off surrounding the lower portion of the antheridium. The opercular cell seems to vary in size for different antheridia. Rupture of the antheridium is initiated by the disorganization of this cell, while in still older antheridia it is generally to be observed that the cells of the outer wall which adjoin this aperture have also broken down, so that the characteristic appearance of the numerous old discharged antheridia on the main prothallus body is that of small brown saucer-like structures projecting from the surface. The details in the formation of the sperms were not followed. I was unsuc- cessful in my endeavour to make the sperms swarm in fresh prothallial sections, and the method of staining was not suitable for showing the details of spermatogenesis. Possibly, also, a better killing and fixing solution would have to be sought for this purpose. The earliest stages in the development of the archegonium are to be distinguished by the very large size of the nucleus in the inner cell. As in the young antheridium, the first wall to be formed is a periclinal by which an outer is cut off from an inner cell. The outer or neck cell divides next by an anticlinal wall (figs. 35, 36), a surface view showing that two such walls are quickly formed intersecting at right angles, so that the archegonium neck-cells have the usual quadrant form (fig. 15). These four cells give rise to the neck of the archegonium, and soon project sharply beyond the surrounding epidermal cells (figs. 36 to 38, and 40). My preparations show that up to this point the inner cell has not divided, but has merely pushed up slightly between the neck-cells along with the Hollowat. — The Prothallus and Young Plant of Tmesipteris. 19 Figs. 35-49. — Series showing development of the archegonia. Figs. 35-41 x 150; fig. 42 X 137; figs. 43-49 X 150. Figs. 50a, 50b. — Series of transverse sections through mature archegonium from above downwards. X 137. 20 Transactions. outward growth of the latter. Thus a basal cell to the archegonium is not formed. In figs. 39, 41, and 42 it will be seen that the large nucleus of the inner cell next divides, and a horizontal wall is formed, this (according to my interpretation) cutting off a neck-canal cell from a central cell. This neck-canal cell seems to be evident in the slightly older archegonia shown in figs. 43 and 46. The neck-cells lengthen considerably, and divide by horizontal walls generally two or three times, so that a straight neck is formed (figs. 15, 45, 46) of three or four tiers of cells. The neck- canal cell pushes up between the neck-cells, and probably divides once or twice in the usual way, although I could not demonstrate this, except perhaps in the instance shown in fig. 45 — much less was a ventral-canal cell to be traced. In fig. 15 is shown the rounded apical head of a small prothallus branch on which two archegonia will be seen with protruding necks. In these cases the neck consists of the lowest tier of cells, which have already taken on the characteristic brown coloration, and an upper tier of elongated cells which will divide again by two or three horizontal walls. As soon as the outermost tier separate the neck-canal becomes conspicuously brown. Sooner or later, after the archegonium has matured, the outer three or four tiers of neck-cells fall off, leaving only the lowest tier, whose walls become strongly cutinized. These cells have already assumed the brown colour in their walls, and their nuclei and contents soon do the same. The exposed horizontal walls of this tier of four cells slope inwards towards the canal in a saucer-like form (fig. 15). Although an occasional old archegonium may be seen on the older parts of the prothallus still showing the full length of neck, yet the characteristic appearance of old archegonia is that just described, the four brown rather peculiarly projecting neck-cells, which originally constituted the lowest tier in the neck, surmounting the brown egg-cell (figs. 47 to 49). A close inspection not infrequently shows the remains of the broken-off cell-walls still attached to the outer surface of these persisting neck-cells. The Development of the Embryo. Unfertilized old archegonia are abundant on most parts of the main prothallus-body, and are very evident on account of the brown colour of the egg-cell and of the persisting lowest tier of neck-cells. I sectioned a good number of large prothalli on which I found no fertilized archegonia at all, but there were several prothalli on which I found both fertilized archegonia in which the egg-cell had not as yet shown any cell-division, and also several young developing embryos. Also I obtained a number of pro- thalli which bore single young plantlets in various stages of development, while most of the largest prothalli showed the presence of the ruptured cup-like eminence from which a young plant had become detached. Thus although developing embryos do not occur on the prothalli of Tmesipteris as numerously as in certain of the large terrestrial species of Lycopodium prothallus (vide, e.g., Bruchmann, 1898, p. 37), yet it ought to be pos- sible to obtain a complete series. It was to be noticed that in several instances both the fertilized archegonia and also the developing embryos were grouped, whilst one embryo was found close alongside the point of attachment of a young plantlet. Fig. 17 shows a transverse section of a prothallus in which two fertilized egg-cells are to be seen. It may be noted here that I found Delafield's haematoxylin a satisfactory stain for differentiating clearly the young embryos from the surrounding tissue. After fertilization the egg-cell grows considerably in size (figs. 17, 51, 52) Hollow ay. — The Prothallus and Young Plant of Tmesipteris. 21 Fig. 51. — Longitudinal section of fertilized archegonium. X 175. Fig. 52. — Longitudinal section of two fertilized arehegonia, in one of which segmentation has begun. X 175. Fig. 53. — Longitudinal section of very young embryo, showing earliest segmenta- tion. X 175. Fig. 54.— Median longitudinal section of young embryo. X 137. Fig. 55. — Median longitudinal section of young embryo. X 137. Fig. 56. — Tangential longitudinal section through upper portion of same embryo as shown in fig. 55. X 137. Fig. 57. — Median longitudinal section of young embryo. X 137. 22 Transactions. and the nucleus retreats (at first, at any rate) to the inner end of the cell. The ovum surrounds itself with a delicate membrane, which arches up somewhat into the base of the neck-canal of the archegonium and at that point thickens. It grows to a fairly large size before it segments, somewhat, though not to the same extent, as Bruchmann has described in the case of Lycopodium clavatum and L. annotinum (Bruchmann, 1898). The first division wall to be formed is more or less transverse to the axis of the archegonium, and seems to be approximately in the middle of the cell (figs. 52, 53). This wall thus divides the embryo into what we may speak of as the lower and upper regions. This first division may be clearly traced afterwards in older embryos. The next division wall to appear is in the lower half, and extends at an angle from the first wall to the lower end of the embryo (figs. 52, 53). It also may be clearly seen in older embryos. No embryos were found in transverse section, so that this description of the earliest stages in segmentation can only refer to the appearance of the embryo in longitudinal section. Still older embryos are shown in figs. 54, 55, and 57. I find it difficult to describe with any degree of certainty the sequence of segmentation which has taken place either in the lower or in the upper parts of these embryos. In addition to the section of the embryo shown in fig. 55, already referred to, a second section (fig. 56), obviously not so nearly median, shows a part of the same embryo which I am inclined to think is the stem-rudiment. In it there are two main walls intersecting at right angles, and in one of the cells so formed another wall has appeared cutting out what might well be an apical cell. This part of the embryo took the haematoxylin stain rather more darkly than did the rest, and the nucleus of the " apical " cell was conspicuously large, the suggestion being that this part was forming rapidly. It will be evident from a comparison of the two sections of this embryo that this portion which we are now considering belongs to the upper region and has arisen laterally from it. If it proves to be correct that the shoot originates from the upper half, this fact would distinguish the embryo of Tmesipteris from that of the Lycopodinae, where the upper primary segment constitutes a suspensor, but would, on the other hand, suggest the embryo of Equisetum and the Ophioglossaceae. Of course, one main reason why the em- bryo of Tmesipteris is likely to prove of special interest is the fact that the adult plant has no root, consisting only of an underground branched rhizoid- bearing rhizome and an aerial branched leaf-bearing portion. Anticipating here what I shall be bringing forward in connection with the developing plantlet, we may say that the young plant of Tmesipteris is " all shoot," just as the embryo of certain members of the Ophioglossaceae has been described as " all root." The question naturally arises whether there is in the embryo of Tmesipteris anything which may be interpreted as the undeveloped rudiment of a root. Only a much fuller study of the develop- ment of the embryo than that given above can satisfactorily decide this point. I hope to be able to gather more material for such a study. The stages described above stop short at a most interesting point, and I have found it difficult to interpret sonic of them. Keeping pace with the growth of the embryo, the surrounding prothallial cells rapidly subdivide, so that the embryo is enwrapped by a small-celled tissue which soon begins to project as an eminence from the side of the prothallus (figs. 55, &c). Before passing on to the section of this paper which deals with the developing plantlet there is still an important and interesting point to be brought forward which concerns the question of the " foot " of the Trans. N.Z. Inst., Vol. L. Plate II. '. . Longitudinal section, prothallus of Tmesipteris, showing young plant attached. ( Photomicrograph. ) lace />. 22. \ Trans. N.Z. Inst., Vol. L. Plate III. % ■* r' jTy Longitudinal section, point of attachment of young plant of T mesipteris to the prothallus. (Photomicrograph.) Holloway. — TJk Prothallus and Young Plant of Tmesipteris. 23 embryo. Longitudinal sections through the point of attachment of a young plantlet to its parent prothallus. such as that shown in tigs. 58 and 59, and in Plates II and III, in all of which the plant-axis is in transverse section, hut the foot in longitudinal section, reveal the fact that the region of the plantlet which is m immediate contact with the prothallial tissues— i.e., the " foot " or absorbing region is prolonged into a large number of long haustoria-like processes, which penetrate the tissues of the prothallus and evidently function as absorbing organs. These processes are generally two cells wide at their base, whilst the forward end of each is prolonged info a row of single cells, the terminal cell of the row being more or less elongated Fig. 58. — Transverse section of young plantlet through point of attachment to prothallus. showing foot and haustorial outgrowths. X- 42. and rounded. They emanate, appearing in section like the fingers of a hand, from a region which consists largely of cells which are dividing. The cells both of the processes and of the region from which they arise stain very conspicuously with haematoxylin both in their walls and nuclei. In trans- verse section the processes are circular in outline. This will be seen in fig. 60, which also shows the nature of the surrounding prothallial cells. On the side towards the plant-axis the cells gradually increase in size, and median sections through the whole plant-foot reveal the fact that vascular tissue, both xylem and phloem, extends from the plant-axis into the foot. In fact, longitudinal sections of detached plantlets of similar age such as that shown in fig. 68 indicate that the entire vascular bundle of the young plant inclines at an angle into the foot. The obvious explanation would be that at an early stage in the development of the young plant 24 Transactions. an apical meristem is set apart from which a plerome strand arises, and that this strand of tissue functions solely in the transportation of food from the parent prothallus up to the growing apex of the shoot. There is nothing to indicate a possible root-rudiment. The haustorial processes are many in number, and no one of them more than any other could be suspected of being such a degenerate or arrested root organ. There is also the broad zone of meristematic cells lying between these processes and the axis of the plant. Of what nature is this ? Only a series of embryos more complete than that described in this paper can indicate at all satis- factorily the first differentiation of the embryo into shoot and foot, and whether or not a root-rudiment is present. If the shoot develops from the lower half of the embryo, then there would necessarily have to be a curvature in the forward growth of that region (as in the Lycopodium embryo) so as to allow the shoot to emerge, as it certainly does, at the apex of the prothallial eminence on which the embryo has been developing. The segmentation in the upper primary half of my embryos is certainly not as clear and regular as it is in the epibasal region of the Equisetum embryo, which there gives rise to the shoot-axis ; but, on the other hand, it does not suggest the Lycopod suspensor. My own opinion, based upon the study of the embryos described in this paper and of the young plantlets. is that the shoot arises from the upper region (i.e., nearest the arche- gonial neck), and that the lower half gives rise only to the foot, the surface cells of the latter growing out into the peculiar haustorial processes. I see nothing to indicate a root. There is no cotyledon, the first leaves being formed at a very late stage as mere scales from the apical cell of the shoot after the latter has emerged from the surface of the humus and has changed its character from a rhizome to a green aerial stem. A still younger plantlet than that just described is shown in median longitudinal section in figs. 61 and 62. The shoot took the form of a globular protuberance from the surface of the prothallus. Sections through the foot showed that the characteristic haustorial outgrowths were only in the first stages of formation. The spherical shoot showed at one point a slightly conical projection, which in section was seen to be composed of meristematic tissue. This was obviously the actual apex of the shoot, but no vascular strand had as yet arisen from it. The main portion of the shoot consisted of large uniform cells in which the coils of the mycorhiza were already established. The apical region consisted of smaller regularly arranged cells, free from fungus, and showing conspicuous nuclei. I was not able to distinguish whether or not there was a single, apical cell present. Fig. 61 shows the plant as a whole in median longitudinal section, but the shoot-apex is cut somewhat obliquely, as its direction of growth did not coincide with the plane of the section. From a study of this particular plantlet I am still more of the opinion that the embryo gives rise to two main organs only — viz., the foot and the shoot — the former arising from the lower half and the latter from the upper. Whether or not a definite stem-apex is differentiated early in the embryo my material does not show, although the embryo shown in fig. 56 would seem to indicate this. Development op the Young Plant. A good number of prothalli were found on which single young plants in various stages of development were borne. Also, I dissected out of the tree-fern humus a large number of complete plantlets which had become Holloway. — The Prothallus and Young Plant of Tmesipteris. 25 Fig. 59. — Section through point of attachment to prothallus of same young plantlet as shown in fig. 58, to show manner of detachment of plant from prothallus. X 42. Fig. 60. — Tangential section through foot of young plantlet shown in fig. 58, showing haustorial outgrowths in transverse section. X 125. Fig. 61. — Median section through very young developing plantlet, showing foot and apical region. X 84. 26 Transactions. detached from their parent prothalli. I am thus able to give a connected account of the development of the young plant. The earliest stages, in which the young shoot has just broken through the surface of the prothallus, and before a vascular strand has made its appearance (see fig. 61), has >■/;■/■& i i // yU/- Fig. 62. — Section through foot of same young .plant let as shown in fig. 61, showing outgrowth of epidermal cells of foot. X 74. Fig. 63. — Transverse section of young plantlet similar to that shown in fig. 68, showing PJ initiation of secondary apex of growth. X 64. Fig. 64. — Very young detached plantlet, showing apex of growth, and fragment of prothallial tissue attached to foot. X 18. Fig. 65. — Very young detached plantlet, showing foot and both primary and secondary apices of growth. x 16. Ftg. 66. — Young developing plantlet attached to prothallus ; secondary apex of growth not yet developed. X 8. been described at the end of the last section. The shoot-apex in this particular plantlet had already been differentiated, though precisely at what stage in the development of the embryo I cannot say for certain. The subsequent elongation o the originally spherical shoot takes place at this apex. In figs. 64 and 65 are shown two early stages in the develop- Holloway. — The Prothallus and Young Plant of Tmesipteris. 27 ment of the young plant, in these cases the plantlets having become detached from their parent prothalli during the process 0f dissection. I have no plantlets of this age in section, but judging from its conical and somewhat pointed shape I would say that the actual apex is occupied by a single apical cell. That end of the young plant which is opposite to the growing apex is obviously the " foot " or absorbing region, where the plant was in connection with the prothallus. In the detached plantlets shown in figs. 64 and 65 this end is roundish in outline, it being evident that the haustoria-like processes of the foot had been left embedded in the tissues of the prothallus. Still older plantlets consist of a lengthen- ing undifferentiated rhizome, golden-brown in colour, thickly clothed with long straight golden-brown rhizoids. Where the rhizoids are broken off, characteristic ring-like outgrowths are left projecting slightly from the epidermal cells. The latter are brown in colour, and, owing to the clear colour of the rhizome generally, stand out very distinctly in outline. The original point of attachment of a detached plantlet of this age to its parent prothallus can always be readily distinguished as a dark circular patch situated on a slight but distinct conical prominence at the basal end of the rhizome. Sometimes there is a brown fragment of prothallial tissue which may show old sexual organs still attached to this foot- prominence. The manner of detachment of the plant from its prothallus may best here be described. It was found during the process of dissecting that the plantlets very easily become detached from their parent prothalli. Reference to the longitudinal section of the plantlet and prothallus given in fig. 59 will show that a saucer or cup-shaped line of dehiscence extends from the edge, where the developing plant has ruptured the tissues of the prothallus, down into the central regions of the foot. This line of dehiscence is clearly marked out by the browning of the cell-walls along the line. Figs. 58 and 59 show clearly both how readily the plant can become detached from the prothallus, leaving behind in the tissues of the latter the haustoria-like processes, and also how the large cup-like point of attachment, which so often is a characteristic feature on full- grown prothalli, comes to be formed. All the youngest plantlets found, whether detached or still in connection with the prothallus, showed only one apex of growth, the other end of the plantlet being bluntly rounded and in no way differing in external appear- ance from the rest of the rhizome surface (figs. 66 and 67). The point of attachment to the prothallus was at this undifferentiated end of the plant. Longitudinal sections of the prothallus and plant shown in fig. 66 revealed that there was nothing at this end of the plant to indicate an apex of growth. Sooner or later, however, a new apex of growth is differentiated at this point (figs. 1, 68, 69), and the young rhizome then proceeds to grow in length in a direction more or less exactly opposite to the primary direction of growth. This new portion of the plant- rhizome is sometimes in a straight line with the first-formed shoot axis (fig. 70), but more often is inclined to it at an angle, the brown point of attachment in the latter case being then to be seen on the angle (figs. 65, 69, 71). In some instances this secondary apex of growth was not differentiated until the plant had attained a considerable size (figs. 67, 68, 69), but in others, again, it was differentiated early (fig. 65). In fig. 1 is shown a plant attached to its prothallus in which the main shoot had a very irregular and peculiar appearance, and at the base of 28 Transactions. which the new apex of growth could be seen. In longitudinal section it was seen that the rounded protuberance at the base of the plant shown in fig. 68 was formed by a surface group of actively dividing meristematic cells (a single apical initial could not be traced), and that from this meristem a plerome strand connecting with the central strand of the plant was in process of formation (fig. 63). Also it was seen that two tracheides were leading out from the centre of the plant-axis towards the new apex. Thus we may say that the development of the new axis of growth is adventitious, and may compare it with the well-known adventitious origin in the epidermal and outer cortical cells of older rhizomes of groups of meristematic cells which are frequently to be observed either in a state of arrested development or about to develop into lateral buds. It must, however, be noted that whereas these lateral buds are not confined to any part of the rhizome, but appear in a quite haphazard manner, the secondary apex of growth in the young plantlet is always differentiated in the one position. Thus there is no root to be distinguished in the young plant of Tmesipteris, there being developed, both above and below the original foot, a rhizome identical in the two cases in appearance, function, and manner of growth. A series of transverse sections through the foot of a young plant which consists of both primary and secondary rhizome portions — such, for example, as that given in fig. 72- — shows that there is a continuous vascular strand throughout the whole rhizome, identical in structure in the two portions of the rhizome, and unbroken in the foot region. Before the secondary apex of growth is differentiated in the young plant the vascular strand inclines bodily into the foot. When the new apex is formed a plerome strand is differentiated from it, and it would appear that this joins on with the primary strand at the angle where the latter inclines into the foot. Possibly the first vascular elements in this secondary strand are actually formed from the angle of the primary strand in connection with the transport of food from the prothallus to the new apex. In fig. 63 is shown the stage at which the plerome strand of the secondary portion of the rhizome is in its earliest development, but vascular elements seem to be leading out to meet it from the point where the strand of the primary part of the rhizome leads down into the foot. The growing apices of the young developing plantlets are whitish-grey in colour and more translucent than the rest of the rhizome, and are often slightly swollen. In this respect, and in the general appearance of the young rhizome, there is a certain similarity between detached portions of prothalli and of young plants. The fungal coils are present in the cortical cells of young plants which are still attached to their prothalli, but apparently the fungus does not spread from the prothallus to the plant, but the latter is early infected through its rhizoids. Several of the young rhizomes bore short swollen lateral shoots (fig. 72), clear or almost light-green in colour, and one frequently noticed on the rhizomes of both young and older plants points of meristematic activity. Besides this adven- titious method of branching, the rhizome-apex may fork dichotomously (fig. 75). Sooner or later one or other of the main ends of the young rhizome grows upwards as an erect aerial shoot, losing its rhizoids and decreasing in thickness in the transition region. The aerial shoot is at first whitish in colour and is quite devoid of both rhizoids and scale leaves, but at length its apex becomes green and gives rise to the first scale leaves (figs. 5, 73, 74). After a few of these scale leaves have been formed, Holloway. — The Prothallus and Young Plant of Tmesipteris. 29 larger leaves of the characteristic form take their place. Both ends of the young rhizome may in some cases emerge from the humus as aerial stems (fig. 73). The actual apex of the young aerial shoots is slender and sharply conical (figs. 5, 73, 74), and even in surface view under a low power of the microscope the single apical cell can be seen. In longitudinal section the apical cell and the order of segments cut off from it is almost diagrammatically clear (fig. 77). The broader apex of young rhizomes also shows a single apical cell (fig. 76). In several instances young plants of a considerable size, showing differentiation into both subterranean and aerial portion, were found still attached to their prothalli, the latter being in some cases firm and health v (figs. 5, 73), and in others old and withered (figs. 9, 10). Fig. 67. — Young detached plantlet. showing fragment of prothallial tissue attached to foot ; secondary apex of growth not yet developed. X 8. Fig. 68. — Young plantlet attached to prothallus, showing secondary apex of growth. X 5. Fig. 69. — Young detached plantlet, showing foot and secondary apex of growth. X 7. Fig. 70. — Young detached plantlet, showing foot and also primary and secondary apices of growth on either side of foot. The two apices are not inclined to one another at an angle. X 8. Fig. 71. — Young detached plantlet, showing foot and also primary and secondary regions of rhizome on either side of the foot. X 6. Fig. 72. — Young developing complete plant, showing foot and also lateral bud; the latter and the two apices are swollen. X 4. • Development op the Vascular Anatomy. The anatomy and morphology of the adult plant of Tmesipteris has already fairly recently been described by Miss Sykes (1908), so that there is no need for me to go over this ground again. Miss Sykes's material came from New Zealand, and she notes that it comprised two forms which 30 Transactions. had previously been separated by some writers as two species — viz., as T. tannensis and T. lanceolata. She gives figures of the aerial stems of these two forms. In the section in the present paper which deals with " Occurrence and Habit " I noted the fact of these two forms, and indicated that the prothalli and young plants which I had obtained belonged to the form which grew to the greater size and had the more pendulous and flaccid habit and possessed the larger leaves. This is the form referred to by Miss Sykes as T. lanceolata. Cheeseman (1906) does not recognize more than the one species in New Zealand, to which he gives the general name T. tannensis, although in a note he adds, " By some authors it is split up into three or four, distinguished mainly by the shape of the apex Fig 73. — Complete young plant, showing parent prothallus, foot, lateral bud, and also both ends of rhizome developed into aerial stems. X 2. Fig. 73a. — Apex of smaller aerial stem shown in fig. 73. X 9. Fig. 74. — Apex of a young aerial stem, showing initiation of leaf-formation. X 9. Fig. 75. — Apex of rhizome of young plant, showing dichotomy. X 10. of the leaf (which I find to be variable even in the same individual) and by certain histological details, the constancy of which has yet to be established." I have not had access to the papers referred to by both Miss Sykes and Mr. Cheeseman as setting forth the exact morphological and histological details on which the distinction is drawn between the different forms of Tmesipteris, so cannot refer particularly to them. However, I shall be noting in this section of my paper certain details in the stem-structure of the two forms referred to above. Having an abundance of young plants of Tmesipteris of the form T. lanceolata of all stages of growth, I made a study of the development of the vascular cylinder of both the rhizome and the aerial shoot. I have no serial sections of the youngest plantlets, such as those shown in figs. 64 Holloway. — The Prothallus and Young Plant of Tmesipteris. 31 and 65, in which the differentiation of vascular tissue between the shoot- apex and the foot would be in its earliest stages. Transverse sections of plantlets of the same age as that shown in fig. 68 are given in figs. 78, 79, and 80 There is a slight central strand consisting of, in the one case, one, and, in the other, two, narrow scalariform tracheides placed more or less collaterally with a group of darkly-staining phloem elements. Fig. 76. — Longitudinal section of apex of rhizome of young plant shown in fig. 5, showing single apical cell. X 140. Fig 77. — Longitudinal section of apex of aerial stem of young plant shown in fig. 5, showing single apical cell. X 140. Fig. 78. — Transverse section of stem of young plant similar to those shown in figs. 66-68. X 50. Fig. 79. — Transverse section of stele of stem shown in fig. 78. X 200. Fig. 80. — Transverse section of stem stele of another young plant. X 200. There is an endodermis in which the characteristic radial markings are clear. The cortex is uniformly parenchymatous and harbours the fungal coils more especially in its middle zone, whilst the epidermis is cuticularized and individual epidermal cells are prolonged into rhizoids. Longitudinal sections of a young prothallial plantlet similar to that shown in fig. 68 revealed the fact that the vascular strand of the shoot curved bodily round at the base of the plant into the foot, where it ended blindly. From 32 Transactions. sections of the plant and prothallus shown in fig. 66 it was clear that even at this early stage the peculiar brown deposit referred to by other writers in their studies of the mature rhizome of Tmesipteris and Psilotum is present in its first beginnings in the innermost layer of cortical cells. The rhizome and the aerial stem of the plant shown in fig. 5 were similar to each other in their vascular structure, three or four xylem elements lying more or less collateral with a group of phloem. The fungal element was present, in the cortical cells of the rhizome but not of the aerial stem, and in Fig. 81. — Transverse section of stele of rhizome of young plant. X 160. Fig. 82. — -Transverse section of stele of rhizome of medium-grown plant. X 125. Fig. 83. — Transverse section of stele of large rhizome of plant shown in Plate I. X 125. Fig. 84. — Transverse section of stele of aerial stem of young plant shown in fig. 85. X 125. neither case was the brown deposit to be seen. The endodermis was here not so clearly defined as in younger plants. A transverse section of the rhizome of a slightly older plantlet is given in fig. 81, and shows that here the single group of xylem elements is placed centrally in the midst of the darkly-staining phloem, the metaxylem having been formed centripetally. Immediately surrounding the phloem are one or two layers of larger cells, probably to be identified as pericycle and endodermis, whilst the cortex is slightly collenchymatous and its innermost layer shows marked evidence of the brown deposit. The middle cortical zone contains the mycorhizal coils, while the outer surface and the rhizoids had the Holloway. — The Prothallus and Young Plant of Tmesipteris. 33 same brown coloration as has the peculiar deposit already referred to. In the vascular cylinder of a medium-grown rhizome, sectioned at some distance behind the apex, there is a tendency for thin-walled elements to invaginate the centrally placed group of xyleni (fig. 82), and in some sections it was seen that it had separated it into two groups. In these rhizomes the brown deposit can be seen in all stages of formation, and it may be detected also in individual cells in the middle cortex, while the fungal coils have almost disappeared from the cortical cells. In fig. 83 is shown the vascular cylinder of the largest ground-growing rhizomes of the form T. lanceolata obtained by me in Stewart Island. Here the xylem is definitely split up into two main curving plates more or less surrounding a central group of thin-walled elements. The comparison of a number of sections showed that the configuration of these xylem groups was constantly changing, sometimes two adjacent ends of the groups joining, and at other times one or both of the two main groups subdividing so that the number became three or four. It would seem, then, from a comparative study of the rhizomes of plants of different ages, that along with the increase in number of xylem elements in the central cylinder there is a diminishing disposition on their part to cohere in one group, so that the original monarch condition becomes lost and the xylem is disposed in separate plates or groups in the midst of the phloem, the tendency being in the oldest rhizomes for these groups to be arranged more or less in the form of a ring surrounding a central group of thin-walled (so-called " pith ") elements. It must be noted that this alteration in the xylem- grouping is in no wise occasioned by any branching of the stele. In these very large humus-growing rhizomes also it was seen that the fungal element was almost entirely absent from the cortical cells, nor did the latter show any signs of thickening at their angles. The development in size and configuration of the rhizome stele cor- responds in a general way to what Miss Sykes (1908) has described in the gradual differentiation of the stele behind the growing apex of the mature rhizome, except that she refers the splitting-up of the original single xylem group into two or more groups only to the transition region between rhizome and aerial stem. Her material probably did not include such large-sized rhizomes as those examined by me. As I have stated above, in the youngest plantlets which show differentiation into both aerial stem and underground rhizome the vascular cylinder is identical in configuration in both. The stele is monarch, the xylem group containing from two to six scalariform elements. In aerial stems of slightly older plants, however, there is a marked change, the characteristic structure of the adult aerial stem, with its separate mesarch xylem strands, beginning to manifest itself. A transverse section of such a young stem shows the pressure of large adherent leaf-bases forming conspicuous angles to the section (fig. 85), the cortical tissue in the angles containing abundant air-spaces. In the central cylinder there are two groups of xylem, obviously mesarch, on the outer side of each of which is phloem, whilst the tissue separating the two groups has the appearance of ordinary parenchymatous cells (fig. 81). I could not identify endodermis or pericycle. There are in young stems of this age no leaf-traces, the leaves as yet being no more than scale leaves. There is, of course, as in all aerial stems, no fungus present. Again, in the aerial stems of still older plants there are to be seen three such separate groups of xylem (figs. 86 and 87) placed in the form of a triangle, the position of the xylem 2— Trans. 34 Transactions. groups corresponding to the leaf-bases. There is a very slight leaf-trace, consisting of a few narrow phloem-like elements with no xylem. The cortical cells are still thin-walled, but in some sections it is apparent that the phloem and the other parenchymatous elements in the central cylinder are beginning to show a slight thickening of their walls. Lastly, in figs. 88 and 89, are shown the steles of the aerial stems of more mature plants, in which there are five mesarch groups of xylem. In the largest aerial stems of all there is a tendency for neighbouring groups of xylem temporarily to join together, thus forming curving plates (fig. 89). In these oldest stems the phloem and the " pith " elements are partly Fig. 85. — Transverse section of aerial stem of young plant. : 46. Fig. 86. — Transverse section of stele of aerial stem of y:>ung plant shown in fig. 87. X 140. Fig. 87. — Transverse section of aerial stem of young plant. X 46. lignified, as has been described by Miss Sykes (1908, p. 70). In fig. 90 is shown a single xylem strand, illustrating its mesarch character and the lignified nature of the surrounding elements. The leaf-trace is collateral, and consists of two or three xylem elements and a group of phloem (fig. 89). I must remark again that the plants of various ages which I examined, and which are described above, all belonged to the particular form of Tmesipteris referred to as T. lanceolata. In none of the aerial stems of this form did I find the cortex collenchymatous, or the presence of the brown deposit in its innermost cells. This is in con- trast with what Miss Sykes states in her paper (1908, p. 70), for she found Holloway. — The Prothallus and Young Plant of Tmesipteris. 35 both these characters present in the aerial stems. I sectioned also some material, obtained from a tree-fern, which presented a very typical example 3& iRbWP^ °t%Jr Fig. 88. — Transverse section of aerial stem of mature plant. X 60. Fig. 89. — Transverse section of aerial stem of mature plant, showing coalescence of neighbouring xylem groups into bands, and also a leaf-trace. X 60. Fig. 90. — Transverse section of single xylem group in stele of aerial stem of mature plant. X 175. Fig. 91. — Transverse section of base of aerial stem of mature plant of Tmesi- pteris tannensis which showed characteristic short erect xerophytic habit, showing strongly lignified cortex and presence of brown deposit. X 50. Fig. 92. — Longitudinal section of stele of rhizome of same material as that indicated under fig. 91, showing method of deposition of brown sub- stance in inner cortical cells. X 70. of the form illustrated by Miss Sykes as T. tannensis. The aerial stem was short and suberect and very compact in habit, and the rhizome firm and brittle. A transverse section taken towards the base of this particular 2* 36 Transactions. stem is shown in fig. 91, in which it will be seen that the cell-walls of the entire cortex are strongly thickened (taking both the safranin and the haematoxylin stain) and that the brown deposit is also present. In fig. 92 is shown the vascular cylinder of the same region of the stem in longitudinal section, in which there is a good example illustrated of the progressive method of deposit of the brown substance in the inner cortical cells. The conclusion I would drawT is that whereas the general configura- tion of the vascular tissues is the same for both forms, T. tannensis and T. lanceolata, as regards both the rhizome and the aerial stem, yet there are certain less important but constant histological differences between them. The rhizome of T. tannensis does not attain as large a size as that of the loose-humus-growing T. lanceolata, and hence does not show the same extent of development of vascular tissues with the consequent splitting-up of the xylem into constantly changing groups. Also, in the drooping aerial stem of T. lanceolata there is an absence of the thickening of the walls of the cortical cells and of the formation of the brown deposit, both of which features are present in the more xerophytic stem of T. tannensis. From the present study it would seem that there is no great difference between the stele of the rhizome and that of the aerial stem, and this one would expect, seeing that they are merely different regions of the plant- shoot, differing only in function. Any of the rhizome-branches are able to emerge from the surface of the humus and develop leaves. In the youngest plantlets the shoot is all rhizome, and one or both ends of it turn upwards and acquire the aerial habit. The rhizome portion functions largely probably as a storage organ, bearing rhizoids, harbouring an abundant mycorhiza, and showing the presence of starch in the cortical cells. The aerial stem shows an absence of all these characters, but the comparatively large leaves, with their strongly decurrent bases and the fertile structures, constitute its dominant feature. In the youngest plants the configuration of the vascular tissues is identical in both rhizome and aerial region. In both, as the number of vascular elements increases, there is manifested a disposition for the xylem to arrange itself in groups surrounding a central " pith," this being more marked and definite a feature in the aerial stems, probably on account of the influence of the leaf-trace system. In the aerial stems the xylem strands are character- istically mesarch, and Miss Sykes has shown that this is so also in those parts of the rhizome where the xylem is arranged in separate strands. In both there is a disposition for neighbouring xylem strands to coalesce to form curving plates of tissue surrounding the central pith as by a broken ring. Thus the nature of the full-grown stele throughout the Tmesipteris plant, and the manner of its development both at the apex of the mature rhizome and in the young plant, from the monarch or collateral condition, through the stages of diarch, triarch, and quadrarch to the ring-like con- dition, may be closely compared with the form and development of the stele in the adult plant of Psilotum triquetrum such as Miss Ford (1904) and Mr. Boodle (1904) have described it. In his paper Boodle traces the similarity between Tmesipteris and Psilotum with regard to the stem- anatomy, and shows that one great point of difference between them — viz., the mesarch structure of the xylem strands in the aerial stems of the former — to a certain extent breaks down owing to his discovery of isolated instances of mesarch structure in the lower regions of the aerial stem of Psilotum. Holloway. — Tht Prothallus and Young Plant of Tmesipteris 37 In view of the fact that Boodle and others have found secondary xvlem in the transition region of the stem of Psilotum, I closely examined the stems of Tmesipteris from this point of view, but found there no traces of it. Also, it may be mentioned that I did not find any evidence of vegetative propagation in Tmesipteris corresponding to the formation of bulbils (Brutknospen) described by Solms-Laubach (summarized in Engler and Prantl, 1900, pp. 612-14) for Psilotum. The long aerial stems of T. lanceolata are sometimes branched, but I did not examine the branch- ing of the stele. It is interesting to note that on the fertile stems the sporophylls occur in clearly defined regions corresponding to the habit so well known in Lycopodium Selago, and that on the longest stems as many as five or six such fertile regions may sometimes be observed separated from one another by sterile regions. Comparative Remarks. It now remains for me to compare the prothallus and young plant of Tmesipteris as described in this paper with what has already been brought forward by other writers wTith regard to the gametophyte generation in the Psilotaceae, and also to include in this comparative survey certain other pteridophytic types of prothallus. Lang's prothallus (1904), which he has provisionally assigned to Psilotum, conforms to a type which certainly differs markedly from that of Tmesipteris as described by Lawson and in the present paper. The differentiation of the prothallus into vegetative and reproductive regions with the meristem located between them, the organization of fungal zones and their evident influence upon the form and structure of the prothallus, is in striking contrast to what has been described for Tmesipteris. This we would probably not have expected, considering the strong morpho- logical and anatomical resemblances between the two genera with respect to the adult plant. And yet, after all, there is not much greater difference between Lang's prothallus and that of Tmesipteris than what there is between, for example, the subterranean and the epiphytic- types of Lycopodium prothalli ; and we have come to look upon the latter as being but different modifications of a common funda- mental structure of Lycopodium prothallus. Lang notes that the prothallus described by him is ' practically identical with [that of] Lycopodium comphuiatum " (1904, p. 576), and goes on to show that it would not lie surprising if the prothallus of Psilotum were of the subterranean type, for it commonly grows as a terrestrial plant as well as an epiphyte. Apparently he did not obtain from this single prothallus any information with regard to the archegonium or embryo ; but as re- gards the structure of the antheridium there is certainly a great difference between what he has described and what is now known in the case of the antheridium of Tmesipteris. However, there is nothing to be gained by drawing out any further this comparison, for Lawson (1917a, p. 786) states that he has discovered '" a single specimen of a structure that he believes to be the prothallus of Psilotum . . . [and that this] bears no resemblance to the supposed prothallus described by Lang." In a later paper he has described the prothallus of Psilotum, but this account I have not yet seen. The point that I wish to emphasize here is that in view of the remarkable diversities in form and structure known amongst the prothalli of the various species of Lycopodium we cannot regard the fact of the great difference in these respects between Lang's prothallus 38 Transactions. and that of Tmesipteris as constituting a valid argument against the possibility of the former belonging to the Psilotaceae. I must enter more into detail in comparing Lawson's observations on the prothallus of Tmesipteris with my own, because although it will be clear that they correspond in many particulars, yet it will be just as obvious that the two accounts differ in many other respects. First of all, then, with regard to the similarities in the two accounts. The prothallus is shown in both to be subterranean and saprophytic in habit, of a characteristic brown colour, and covered with numerous lonu rhizoids. It is cylindrical in form, is not differentiated into reproductive and vegetative regions, and can branch. There is an endophytic fungus which is found in any part of the prothallus-body and is not localized in definite zones. The antheridia and archegonia are intermixed, and are distributed in large numbers over practically all parts of the surface of the prothallus. The two accounts of the structure of the mature sexual organs are closely similar. The embryo is carried on a distinct pro- tuberance of the prothallial tissues, the result of localized meristematic activity in the cells of the latter keeping pace with the development of the embryo. The embryo shows a hypobasal and an epibasal portion, the latter being characterized by a peculiar development from its surface of lobes or protuberances. This general similarity in the two sets of prothalli and their essential organs might be sufficient to show that they both belong- to the same order, Psilotaceae, or even also to the same genus, Tmesipteris. But there are also some very striking differences between them which must be considered. To begin with, Lawson states that, " compared with the Lycopodiales and other Pteridophytes, the prothallus of Tmesipteris is small." His largest specimen measured only I in. in length. My prothalli, except the very youngest, were very large compared with this, several of the largest being up to f in. in length. The tissue of Lawson's prothalli " is extremely soft t,nd fragile," and easily destroyed in the process of cleaning with a camel's-hair brush, whereas my prothalli are firm and solid and thick, and are very favourable objects for hand-sectioning in elder-pith. A small but striking point of difference lies in the fact that Lawson describes the rhizoids as characterictically twisted, but in my figures they are shown as perfectly straight. Lawson speaks of the endo- phytic fungus as being " more conspicuous in the surface cells and those near the surface,'" although it may extend into the very interior of the prothallus. I found that it was only in the oldest and lowest regions of the prothallus that the fungus inhabited the epidermal cells and those of the cortex immediately underlying it, but that it was uniformly present throughout the prothallus-body (except, of course, at the growing apices) in the more centrally placed cells. A comparison of figs. 1, 2, and 3 in Lawson's paper with any of those in mine which show the complete prothallus will reveal a noticeable difference in the fact that in the latter cases there is always a bluntly rounded apex to each branch of the prothallus, the growing apices usually taking the form of a swollen head, whereas in the former the ends of the branches are shown (if not broken) as pointed structures. It will be noticed that these differences between the two accounts relate entirely to the external form of the prothallus and the disposition of the fungal element. The appearance and structure of the mature sexual organs is identical in both accounts. I must here point out that the archegonia as seen and figured by Lawson, and described by him as being very simple and peculiar, are only the old organs which, as has been shown in the present paper, have lost the upper tiers of ceck -cells. Holloway. — The Prothallus and Young Plant of Tmesipteris. 39 If it were not for the fact that in Lawson's figures of the prothallus some of the pointed ends of the branches are shown as complete and unbroken, I would be inclined to think that his specimens were merely fragments of old prothalli and not complete ones. All the points of difference enumerated above seem to point to this ; and there is another fact which bears upon the same point — viz., that in none of the prothalli figured by him does he show a meristematic region. There is, how- ever, quite another explanation of the differences between our prothalli, which is that whereas mine belong to the form sometimes spoken of as T. lanceolata, which, as I have shown, differs from the other form, T. tannensis, not only in general habit but also in certain histological details, Lawson speaks of his prothalli as those of T. tannensis. We have become so familiar with the fact of the manifold variations in the types of prothallus of the different species in the genus Lycopodium — new variations being found in almost each additional species discovered — that it is not unlikely that the prothalli of Tmesipteris as described in the two accounts will be found to be those of two different forms which have hitherto been grouped under the collective name T. tannensis. The fact that Lawson's prothalli were obtained by him almost singly from widely different localities and in different years indicates that they represent a constant type of prothallus. The prothallus of Tmesipteris shows certain resemblances, such as its cylindrical, radially symmetrical, and more or less drawn-out form, its apical growth, and its branching, to certain other pteridophytic types of pro- thallus, such as those of the epiphytic Lycopodiaceae and Ophioglossaceae and Helminthostaehys. But these resemblances are only what might be looked for in prothalli having the same epiphytic habit. Even with regard to these general characters the resemblance does not hold quite closely, whereas in the. matter of other main features, such as the nature of the basal (or k primary tubercle ") region, the distribution of the fungal element, and the differentiation of vegetative and reproductive regions in the prothallus, there are striking differences. Thus on a general sum of characters the prothallus of Tmesipteris stands apart from that of both the Ophioglossaceae and the Lycopodiaceae. Still less does it show any evidence of affinity to the prothallus of Equisetum. This conclusion is strengthened by a comparative study of the sexual organs, embryo, and young sporophyte. The antheridium is strongly projecting in a manner almost resembling that of the male organ of the leptosporangiate ferns, whereas that of the Ophioglossaceae and Lycopodiaceae is sunken. How- ever, in the manner of its development it agrees with that of the two latter orders. The archegonium also is peculiar in that there is apparently no basal cell cut off in the young rudiment, and the form of the mature organ is very characteristic. It is not certain from which primary half of the young embryo the shoot and the foot respectively develop, or whether there is or is not a suspensor present. But the peculiar development of the foot into long haustoria-like processes, the total absence of a root, and the dominance of the shoot mark out the embryo of Tmesipteris as bearing very little resemblance to that of any other class of Pterid.opb.ytes. From the single embryo found by him in which three lobes were present on the lower half Lawson is inclined to interpret one of these lobes to be the rudiment of the root, ascribing the others to the foot. The fact that in older stages there are a large number of these lobes present, and that they are all similar in appearance, seems to me to indicate that they are nothing more than haustorial outgrowths; and this would also appear to be borne 40 Transactions. out by the fact that the vascular strand of the shoot is in close connection with them. However, their early appearance in the young embryo is noteworthy. Lawson's embryo presents an interesting stage slightly older than those, described in the present paper, but there is still a gap in the series which conceals the first differentiation of the young stem-apex, although such very young plantlets as those shown in figs. 61, 64, and 65 in the present paper seem to indicate that the shoot arises from the hvpo- basal portion of the embryo. Scott (1900, ]). 499) first pointed out the similarity between the sporo- phyll of the Psilotaceae and that of the Sphenophyllales, and repeated his statements more fully in the second edition of his Studies (1909, pp. 626-31). Thomas (1902) strengthened this idea by showing that the nature of the frequent abnormalities which occur in the sporophylls of both Tmesipteris and Psilotum bring those structures liearer still to those of certain of the Sphenophyllales and especially to that of Cheiro- strobus. Miss Sykes (1908) has also supported this with additional evi- dence by her elucidation of the vascular structure of the sporophyll and synangium of Tmesipteris. Both Bower (1908) and Seward (1910, p. 14) have accepted the suggestion of the affinity of the modern Psilotaceae with the fossil Sphenophyllales. A general similarity in vascular structure in the mature plants of Tmesipteris and Psilotum has been pointed out by various writers, and, as described in the present paper, the study of the development of the stele in both the rhizome and aerial stem of Tmesipteris helps to make the nature of this structure more clear. Scott (1900) noted the similarity between the stem-anatomy of the Psilotaceae and that of the Spheno- phyllales, and Boodle (1904) has developed the idea and made it more marked still by the discovery of what he believes to be reduced secondary xylem in the subterranean parts of Psilotum. There is no need for me to recapitulate here all the details concerned in this double correspondence between the Psilotaceae and the Spheno- phyllale?, for they have been thoroughly co-ordinated and analysed by most of those who have written recentlv on the subject, as, e.g.. Scott (1909), Sykes (1908), and Boodle (1904). The peculiar features of the Psilotaceae are open to interpretation in any of the following three ways : They may be regarded as primitive, or as the result of reduction, or as being recent adaptations. This is so also, of course, in other pteridophytic groups, such as, for example, the Lyco- podiaceae and the Equisetaceae, and an instructive parallel may be drawn between them and the Psilotaceae in this respect. Through our knowledge of the fossil plants of the Carboniferous and succeeding periods we have learned to look upon each of these two groups as being the modern repre- sentatives— mere remnants — of families which dominated the forest of the Palaeozoic age. The modern Lycopods and Equisetums do not show the presence of secondary wood (except in one known instance), and this may indicate either that they have lost it by reduction in their descent from large Carboniferous ancestors which possessed it, or that they are descended rather from humbler ancestors which existed side by side with the tree forms but which had never attained to secondary growth. The comparative study of the stem-stele in the modern Equisetums and the fossil Calamites reveals the presence of a primary structure common to both, so that the modern group in this particular, as also in external form and in the nature of the strobilus, is regarded as preserving primitive characters. The Lycopodiaceae may be read, according to two main Holloway. — The Prothallus and Young Plant of Tmesipteris. 41 theories, either as a reduction series or as a progressive scries, the simpler type of Li/copodium, such as L. Selago, being thus regarded either as very much reduced or as primitive in form. Certain features of the embryo and young plant, moreover, peculiar to a section of the Lycopodiaceae have been interpreted as primitive, and primitive not only for the Lycopodiaceae but for vascular plants generally. These are the protocorm and its sur- CORRIGENDUM. Page 40, lines 7-8 : For hypobasal read upper. has been derived from this particular section by reduction. Again, a third interpretation has been suggested, that the protocorm is a modified form of stem due to reduction, the basis of probability for the truth of this theory being the very large size attained by the Carboniferous ancestors of the Lycopodiums. These varying interpretations of the outstanding features of the Equisetaceae and the Lycopodiaceae are so well known that there is no need for me here to do more than merely indicate them or to cite the authorities. They are mentioned to serve as an analogy to the various interpretations which are possible in the case of the Psilotaceae. It will be necessary for me to discuss briefly the evidence in favour of regarding the Psilotaceae either as reduced forms or as retaining primitive characters. Boodle (1904, p. 511) interprets the secondary tracheides found by him in certain parts of the stem of Psilotum as reduced secondary xylem, and considers that this feature reinforces the similiarity which has been traced between the Psilotaceae and the Sphenophyllales. He speaks of Psilotum and Tmesipteris as being reduced from '* a common parent form, in which the aerial stem had a rayed mesarch xylem mass "' (ibid., p. 515) and which also showed secondary thickening. Such a stem, he says, would bear a strong resemblance to the axis of Cheirostrobus ; but at the same time he is careful to point out that such a character as the presence of secondary xylem is too adaptive to be taken by itself as evidence of affinity (ibid., p. 513, note 1). However, the presence of secondary xylem in the stem of Psilotum, he says, possesses certain significance in view of the fact that the fertile organ of the Psilotaceae finds its nearest parallel in that of the Sphenophyllales. There is no doubt that the saprophytic habit of both Psilotum and Tmesipteris, the extreme reduction in the leaves of the former, and the presence in the rhizomes of a mycorhiza, may be taken as suggesting that their present form and structure is, at any rate partly, due to reduction. And, of course, the absence of a root organ may be regarded in the same way. Probably the most interesting point to be elucidated by a study of the life-history of the two members of this class is whether or not there is a rudimentary root organ to be traced in the embryo. Lawson (1917a, p. 793), from his study of the one embryo found by him, concludes that there is such a rudimentary root present. My own study of a number of embryos and of a fairly complete series of young plants has convinced me that there is not, but that the peculiar outgrowth of the absorbing region of the embryo which Lawson speaks of as a rudimentary root is only one of a large number of such outgrowths which are to be regarded Transactions. -^ of the shoot is in close connection in the young embryo is "-"•re slightly older - in the series .. although sucli vi in the present paper seen" il portion of the embryo. Scott (1900, p. 499) first pointed out phvll of the Psilotaceae and that of the Sphenophyllai.-*. his statements i e fully in the second edition of his Studies u_ pp. 626-31). Thomas (1902) strengthened this idea by showing that" the aature of the frequent abnormalities which occur in the sporophylls of both Tmesijilcris and Psilotwm bring those structures nearer still to those of certain of the Sphenophyllales and especially to that of Gheiro- strobus. Miss Sykes (1908) has also supported this with additional evi- dence by her elucidation of the vascular structure of the sporophyll and synangium of Tmesipteris. Both Bower (1908) and Seward (1910, p. 14) have accepted the suggestion of the affinity of the modern Psilotaceae with the fossil Sphenophyllales. A general similarity in vascular structure in the mature plants of Tmesijfteris and Psilotum has been pointed out by various writers, and, described in the present paper, the study of the development of the stele in both the rhizome and aerial stem of Tmesipteris helps to make the nature of this structure more clear. Scott (1900) noted the. similarity between the stem-anatomy of the Psilotaceae and that of the Spheno- phyllales, and Boodle (1904) has developed the idea and made it more marked still by the discovery of what he believes to be reduced secondary xvlem in the subterranean parts of Psilotum. There is no need for me to recapitulate here all the details concerned in this double correspondence between the Psilotaceae and the Spheno- phyllales, for the}- have been thoroughly co-ordinated and analysed by most of those who have written recentlv on the subject, as, e.g., Scott (1909), Sykes (11)08), and Boodle (1904). The peculiar features of the Psilotaceae are open to interpretation in any of the following three ways : They may be regarded as primitive, or as the result of reduction, or as being recent adaptations. This is so also, of course, in other pteridophytic groups, such as, for example, the Lyco- podiaceae and the Equisetaceae, and an instructive parallel may be drawn between them and the Psilotaceae in this respect. Through our knowledge of the fossil plants of the Carboniferous and succeeding periods we have learned to look upon each of these two groups as being the modern repre- sentatives mere remnants of families which dominated the forest of tin- Palaeozoic age. The modem Lycopods and Equisetums do not show the presence of secondary wood (except in one known instance), and this may indicate either that they have lost it by reduction in their descent from large Carboniferous ancestors which possessed it, or that they are descended rather from humbler ancestors which existed side by side with the tree forms but which had never attained to secondary growth. The comparative study of the stem-stele in the modern Equisetums and the fossil Calamites reveals the presence of a primary structure common to both, so that the modern group in this particular, as also in external form and in the nature df the strobilus, is regarded as preserving primitive characters. The Lycopodiaceae may be read, according to two main HoiiLOWAY. — The Prothallus and Yowig Plant of Tmesipteris. 41 theories, either as a reduction series or as a progressive series, the simpler type of Lycopodium, such as L. Selago, being thus regarded either as very much reduced or as primitive in form. Certain features of the embryo and young plant, moreover, peculiar to a section of the Lycopodiaceae have been interpreted as primitive, and primitive not only for the Lycopodiaceae but for vascular plants generally. These are the protocorm and its sur- mounting protophylls. According to this theory, the protocorm is regarded as an indication of the way in which the primitive sporophvte first became independent of the gametophyte, and in pursuance of this idea the peculiar plant PhyUogJossiim has been spoken of as the most primitive form of Lycopod. However, a simpler explanation of the protocorm, and one widely accepted, is that it is merely a vegetative adaptation peculiar to one or perhaps two sections of the Lycopodiaceae, and that Phylloglossum has been derived from this particular section by reduction. Again, a third interpretation has been suggested, that the protocorm is a modified form of stem due to reduction, the basis of probability for the truth of this theory being the very large size attained by the Carboniferous ancestors of the Lycopodiums. These varying interpretations of the outstanding features of the Equisetaceae and the Lycopodiaceae are so well known that there is no need for me here to do more than merely indicate them or to cite the authorities. They are mentioned to serve as an analogy to the various interpretations which are possible in the case of the Psilotaceae. It will be necessary for me to discuss briefly the evidence in favour of regarding the Psilotaceae either as reduced forms or as retaining primitive characters. Boodle (1901, p. 511) interprets the secondary tracheides found by him in certain parts of the stem of Psilotum, as reduced secondary xylem, and considers that this feature reinforces the similiarity which has been traced between the Psilotaceae and the Sphenophyllales. He speaks of Psilotum and Tmesipteris as being reduced from '" a common parent form, in which the aerial stem had a rayed mesarch xylem mass " (ibid., p. 515) and which also showed secondary thickening. Such a stem, he says, would bear a strong resemblance to the axis of Gheirostrobus ; but at the same time he is careful to point out that such a character as the presence of secondary xylem is too adaptive to be taken by itself as evidence of affinity (ibid., p. 513, note 1). However, the presence of secondary xylem in the stem of Psilotum, he says, possesses certain significance in view of the fact that the fertile organ of the Psilotaceae finds its nearest parallel in that of the Sphenophyllales. There is no doubt that the saprophytic habit of both Psilotum and Tmesipteris, the extreme reduction in the leaves of the former, and the presence in the rhizomes of a mycorhiza, may be taken as suggesting that their present form and structure is, at any rate partly, due to reduction. And, of course, the absence of a root organ may be regarded in the same way. Probably the most interesting point to be elucidated by a study of the life-history of the two members of this class is whether or not there is a rudimentary root organ to be traced in the embryo. Lawson (1917a, p. 793), from his study of the one embryo found by him, concludes that there is such a rudimentary root present. My own study of a number of embryos and of a fairly complete series of young plants has convinced me that there is not, but that the peculiar outgrowth of the absorbing region of the embryo which Lawson speaks of as a rudimentary root is only one of a large number of such outgrowths which are to be regarded 42 Transactions. simply as haustorial protuberances of the surface cells of the foot. If there is no evidence forthcoming that the absence of the root is due to reduction, other than a certain degree of probability arising out of the present habit of the plants, coupled with the fact that in other isolated pteridophytic classes we seem to trace signs of reduction, we must ask, Is there anything to adduce in favour of the theory that the absence of a root in the Psilotaceae is a primitive feature ( In this particular character the Psilotaceae stand alone amongst existing Pteridophytes. The funda- mental differences between the various classes of Pteridophytes in the manner in which the root is differentiated in the embryo shows that those classes have been distinct from one another from a far-distant period, and accordingly if one of them shows the total absence of a root from its embryo this may quite conceivably be due to the preservation in the one particular line of descent of a primitive character of vascular plants. Such a theory will, of course, best be substantiated by direct evidence from the fossil record. Such evidence has lately been brought forward by Kidston and Lang in their account of the fossil plant Rhynia Gwynne- Vaughani (1917). It must suffice here for me to mention briefly those points in their paper which bear directly upon the present subject. The authors themselves state that they have reserved to a later paper their own discussion of the relation of their plant to the important questions concerning the differentiation of primitive Pteridophytes into stem, root, and leaf {ibid., p. 775). Rhynia Gwynne-Vaughani occurs in the Old Red Sandstone of Aberdeen, and is, as its investigators point out, " the most ancient land-plant of which the structure is at all fully known." Fortunately, the plant was preserved in large numbers as it grew, and Kidston and Lang have been able to elucidate fully its general habit of growth, external form, and structure. The plant was leafless and rootless, the branched cylindical stems being differentiated into underground rhizoid-bearing rhizomes and tapering aerial stems. Branching of the stem was by the dichotomous division of its apex, or more frequently by the formation on the stem of adventitious lateral branches. The vascular system of the plant consisted throughout of a simple cylindrical stele composed of a slender solid strand of tracheides, with no distinction of protoxylem and metaxylem, surrounded by a zone of phloem. The possession of these general characters leads Kidston and Lang to compare Rhynia with the existing Psilotales ; but the presence of certain other characters, such as the total absence of leaves, the consistent simplicity of the stele, and especially the single large sporangia borne terminally on short stalks, has decided them to recognize a new pterido- phytic class (to which they propose to give the name " Psilophytales ;') somewhat resembling the modern class Psilotales, and embracing with Rhynia certain Devonian plant fossils. The authors note that the com- parison which they institute between Rhynia and the Psilotf ceae " would lead us to regard the Psilotaceae as having preserved many primitive characters, and not as reduced. On this view the Psilotaceae would be the little-modified survivors in the existing flora of a type of plant that existed in early geological times, the most fully known example of which is now Rhynia Gwynne-Vaughani. It does not follow, however, that a direct line of descent is to be drawn between Rhynia and the Psilotaceae as we know them " (ibid., p. 776). It might, of course, with some reason be argued that the simple morpho- logical nature of Rhynia was due to reduction ; but, all things considered, it is more likely that the characters of this ancient plant are primitive Hollow ay. — The Prothallus ul Young Plant of Tmesipteris. 43 rather than reduced. The account given in the present paper of the life-history of Tmesipteris lends weight to Kidston and Lang's suggestion that the Psilotaceae, on account of their remarkable resemblance to Rhynia, are to be regarded as possessing j)rimitive characters. The structure of the sexual organs, of the embryo, and of the young plant of Tmesipteris confirm the idea that the Psilotaceae should be removed from all other existing classes of Pteridophytes. The structure and form of the prothallus is also peculiar, but probably the gametophyte generation is always too adaptive to form the basis for much generalization. The simple stele found throughout the young plant of Tmesipteris in both rhizome and aerial stem resembles that of the Psilophytales. The theory that the mature plant of the Psilotaceae, as regards both its more complete vascular anatomy and also the nature of its sporophylls, finds in the Sphenophyllales its nearest resemblances is quite compatible with the belief that in other respects the Psilotaceae have preserved the same primitive characters as are exemplified in Rhynia. Just what is the degree of relationship between the Psilotaceae and these groups of fossil Pteridophytes is still, of course, far from clear. But this much, at any rate, may be said : that we have learned to look for the nearest relationships of this peculiar modern class of plants in the fossil record, just as has been done in the case of the Lycopodiums and Equi- setums ; and that while undoubtedly certain outstanding characters in the case of each of these modern remnants of once flourishing and important groups are best interpreted as reduced or even as adaptive, others, again, must be regarded as primitive, for they may be directly compared with corresponding characters in fossil plants. Postscript. At the same time that the proofs of this paper were returned to me from the printer for a second revision Professor A. A. Lawson's second account of the prothallus of Tmesipteris (Lawson, 1917b) was kindly sent to me by its autl or, so that I am able to give in the form of an appendix a short comparison of his corrected results with mine. My own account of the prothallus of Tmesipteris as given above corresponds more closely with that given by Lawson in his second paper than in his first. Since writing his preliminary account Lawson found a large number of prothalli, a certain proportion of which would be more or less complete, at any rate as regards their growing apices. One of these is figured by him (fig. 1). This prothallus shows a close resemblance to those figured in the present paper. Certain differences are due to the fact that Lawson's prothalli occurred terrestrially in a sandy soil, whereas mine were found amongst the tangle of aerial rootlets on tree-fern stems where the humus was scanty. More important differences to be noted are that Lawson does not describe or figure the first-formed tapering region of the prothallus : he describes the branching as irregular, whereas I have shown that it takes place normally according to a regular sequence of dichotomies ; and the growing apices of his prothalli are not swollen, as were most of mine ; also, my prothalli are stouter and more strongly grown. Otherwise, it seems to be clear from our two accounts that our prothalli are identical in nature. My account of the mature archegonia and antheridia corresponds also with that given by Lawson in his second paper. He there corrects his previous account of the mature archegonium, and shows, as I also have pointed out above, that there is a straight 44 Transactions. projecting neck of four tiers of cells, which in most cases in the mature organ falls off almost level with the surface of the prothallus. In figs. 7 and 8 he shows two stages in the development of the antheridium. He gives no account of the embryo in this second paper, but leaves this subject for a still further communication. In the same paper Professor Lawson describes and figures the pro- thallus and sexual organs of Psilotum. Here again his description is based upon ample material. There is no need for me to go into any detail other than to notice that Lawson draws attention to the remarkably close similarity between the prothalli and sexual organs of the two genera. This similarity in the matter of the gametophyte generation hears witness to the very near affinity of Psilotum with Tmesipteris, and serves also to draw our attention to the fact of the essential similarity in the stelar anatomy of the sporophyte. Lawson notes that the prothallus of Psilotum as described by him differs wholly from that which Lang provisionally assigned to Psilotum. I have not seen Darnell-Smith's paper on the gametophyte of Psilotum {Trans. Roy. Soc. Edin., vol. 52, 1917), quoted by Professor Lawson, in which he gives his observations on the germination of the spore, so cannot compare what he there says concerning the first-formed part of the prothallus with what I have described in the present paper in various well-grown prothalli with regard to the same. Literature consulted. Boodle, L. A., 1904. On the Occurrence of Secondary Xylem in Psilotum, Ann. Bot., vol. 18, pp. 505-17. Bower, F. 0., 1894. Studies in the Morphology of the Spore-producing Members, I. Equiset. and Lycopod., Phil. Trans. Roy. Soc. Lond., ser. B, vol. 186. 1908. The Origin of a Land Flora, London. Brttchmann, H., 1898. fiber die Prothallien und die Keimpjtanzen mehrerer europiiischer Lycopodien, Gotha. Campbell, D. H., 1911. The Eusporangiatae — The Comparative Morphology of the Ophioglossaceae and Marattiaceae, Washington. Cheeseman, T. F.. 1906. Manual of the New Zealand Flora. Wellington. Engler. A., and Prantl, K-. 1900. Pflanzenfamilien. Teil 1, Abteihmg iv, Psilo- taceae. Ford, Miss S. O.. 1904. The Anatomy of Psilotum triquetrum. Ann. Bot.. vol. 18, pp. 589-605. Kidston, R., and Lang, W. H., 1917. On Old Red Sandstone Plants, showing Structure, from the Rhynie Chert Bed, Aberdeenshire, Pt. i, Rhynia Givynne- Vaughani, Trans. Roy. Sic. Edin., vol. 51, pt. 3, No. 24. Lang, W. H., 1902. On the Prothalli of Ophioglossum pendulum and Helminthostachys zeylanica, Ann. Bot., vol. 16, pp. 23-56. 1904. On a Prothallus provisionally referred to Psilotum, Ann. Bot., vol. 18, pp. 571-77. Lawson, A. A.. 1917a. The Prothallus of Tmesipteris tannensis, Trans. Roy. Soc. Edin., vol. 51, pt. iii, pp. 785-94. — — 1917b. The Gametophyte Generation of the Psilotacea*?, Trans. Roy. Soc. Edin., vol. 52, pt. i, pp. 93-113. Scott, D. H., 1909. Studies in Fossil Botany, 2nd ed. (1st ed. 1900), London. Seward, A. C, 1910. Fossil Plants, vol. 2, Cambridge. Sykes, Miss M. G., 1908. The Anatomy and Morphology of Tmesipteris, Ann. Bot., vol. 22, pp. 63-89. Thomas, A. P. W., 1902. The Affinity of Tmesipteris with the Sphenophyllales, Proc. Roy. Soc, vol. 69, pp. 343-50. Tretjb, M., 1884-90. Ktudes sur les Lycopodiacees, Ann. duJard. bot. de Buit. (Refer- ences in standard works.) Parry. — Resistance to Flow of Water through Pipes. 45 Art. II. — The Resistance to the Flow of Water through Pipes. By B. Parry, B.Sc, Public Works Department, New Zealand. [Read before the Technological Section of the Wellington Philosophical Society, 7th July, 1917 ; received by Editors, 31st December, 1917 ; issued sepaiatrly, 24>ih May, 1918.] Introductory. In a previous contribution to this subject communicated to the Philo- sophical Society, and printed in the Transactions ot the Neiu Zealand Institute,^' an attempt was made to determine the limits between which the resistance to the flow of water in a turbulent state is found to vary, first, for riveted steel pipes, and, secondly, for wood-stave pipes. This was done by plotting all the experimental determinations of loss of head which are on record and afterwards enveloping the observations as a whole by curves, the form of which was deduced from analogy with the ascertained law of resistance to flow through smooth pipes. In the present contribution an attempt is made to analyse the effect of different surfaces more in detail and to extend the study of the subject. The principle herein employed has been applied by the author to the observations upon the resistance to the flow of water in open channels, and the results communicated to the New Zealand Society of Civil Engineers.! It is well known that the flow of water or any fluid assumes two different modes, the one in which the flow is linear and known as stream- line or viscous motion, and the other in which the flow is non-linear or sinuous, the flow being otherwise described as eddying or turbulent. The two terms "linear" and "sinuous" describe the two states very well, and are used herein in the sense defined. Between the two states there is an unstable region below which the flow is linear and above which it is sinuous. In the linear stage the relationship between the elements affecting the resistance to motion is simple in character, and in consequence the nature of the relationship was discovered by experiment at an early date and subsequently rationalized, and is expressed as follows : — " = a (Z.) v2 \vd) (1) where s is the hydraulic gradient, r the hydraulic mean depth, d the diameter of the pipe, v the mean velocity, v the kinematic viscosity (i.e., the viscosity divided by the density of the fluid), and a a constant. Here the resistance is expressed as a loss of head per unit length of pipe, as is customary in engineering practice, whilst the customary notation has also been adopted — viz., r and s for the hydraulic mean depth and hydraulic gradient respectively. In the sinuous or eddying stage, on the other hand, the relation between the elements of resistance is evidently complex, and as a *E. Parry, Resistance to the Plow of Fluids through Pipes, Trans. N.Z. Inst.., vol. 48, pp. 481-89, 1916. t E. Parry, A Critical Discussion of the Subject of the Fiow of Water in Pip^s and Channels, wi h Special Reference to the Latter, Proc. N.Z. Soc. Civil Engineers, vol. 3, pp. 116-32, 1917. 46 Transactions. consequence the efforts of experimenters to discover the nature of the relationship has been fruitless, and, as little or nothing is known of the transformation of energy within fluids in sinuous motion, a precise mathe- matical solution was impossible. It may, however, be deduced from certain dynamical principles that the resistance is some function of ( — J \vdj provided that there is a proportionality between the dimensions of the eddies and of the cross-section of the pipe, leaving the form of the function to be determined by experiment. The law of resistance, then, in its most general form, which applies to both states of motion, is expressed as follows : — 3-*(a) <2> where <£ stands for " function of" and the other symbols have the same significance as in equation (1). As already explained, the relation between the quantities in the linear state is a simple one, the left-hand expression in equation (2) being a simple linear function of the right hand. As regards sinuous or turbulent flow, it was supposed at one time that the nature of the function was of the form rs />i2 •U" <3> but it is now known that this form is defective, and that the range of observations upon which it was based was not wide enough to determine the true form ; it was soon found that equation (3) did not fit the facts, and in consequence a modification of this was adopted in which v was treated as a constant, and independent indices given to v and d, yielding a formula of the form v = kr*sv (4) where k, x are constants and r is the hydraulic mean depth numerically equal to d/4 for round pipe. This formula is one of considerable flexibility, and of late the whole phenomenon of the flow of water in pipes has been analysed afresh and expressed in the form given in equation (4). Its adoption has not, however, contributed anything towards extending our knowledge of the subject, and it is much to be regretted that steps were not taken to extend the range of observations when equation (3) was found to be defective. Tnis aspect of the question has been apparently overlooked. Such a series of observations extending over a wide range was recently conducted in the National Physical Laboratory by Stanton and PannelP upon oil, air, and water in smooth brass pipes. The diameters of the pipes used varied from 0 142 in. to 5 in., and the mean speed from a fraction of a foot to 20 ft. per second. These combined with other observations upon the flow of water in smooth pipes when plotted with -- as ordinates and log. — as abscissae were found to be sufficientlv v% V near to enable a curve to be drawn through the mean which was fairly representative of the whole, despite the fact that the condition of geometric similarity was not observed in respect to the surface of the * T. E. Stanton and I. R. Pannell, Similarity of Motion in Relation to the Surface Friction of Fluids, Phil. Trans Roy. Soc, A.'vol. 214, pp. 199-224, 1914. Parry. — Resistance to Flow of Water through Pipes. 47 pipes. According to Professor Lees,* the mean curve can be expressed in the form rs n +=a\x) +b (5) the values, the coefficients, and the index being as follows : — a = 0-00801 ; b = 0000028 ; n = 0-35 all the quantities being in foot-pound units. More recently Landert carried out an extensive series of experiments upon the flow of water and steam at speeds varying from 191 ft. per second to 11*55 ft. per second through ordinary commercial drawn-steel pipe of 0*423 in. diameter, and upon plotting the values of — against log. he finds than an equation of the form (5) satisfies the relation between them. He, however, obtains different values of the coefficient and of the indices, the values being a = 00202 ; b = 0*0000622 ; n = 0*44 all values being in foot-pound units. It is evident on contemplating the two sets of experiments that an equation of the form given in (5) correctly expresses the relation between the quantities near enough for all practical purposes, and it remains to be seen how far the principle is applicable to larger diameters and rougher surfaces, and it is the purpose of this paper to test its ap- plicability to cast-iron, riveted steel, and wood-stave pipes of such sizes and characteristics as are in common use in the arts. Before proceeding further in the direction indicated it may be useful and interesting to compare the form of equation (5) with Chezy's formula, viz. : — v = c Comparing this with other well-known formulae for c, we have Prony's equation, viz. : — ■ 1 -^•G) + b whilst Darcy and Bazm's formula may be expressed as follows : — 1 = V"(i) + > Evidently the influence and value of v predominate in Prony's experi- ments, whilst the value of d predominated in Darcy's experiments ; and * C. H. Leks, On the Fiow of Viscous Fluids through Smooth Circular Pipes, Proc. R>>y. Soc, A, vol. 91, pp. 46-53, 1914. f C. H. Lander, Surface Friction : Experiments with Steam and Water in Pipes , Proc. Boy. Soc, A, vol. 92, pp. 337-53, 1916. 48 Transactions. it does not seem to have occurred to any one to combine the two and thereby obtain an approximation to equation (7). Kutter's formula for c is too complicated for ready comparison, and, after all, what is required is not a formula for c, but a sufficient number of observations for each class of pipe to enable a curve to be drawn correlating — to — The precise form of the equation expressing the v v relationship is really only of academic interest. Returning to equation (5), the results of the experiments on smooth pipe by Stanton and Panned are plotted in figs. 1, 2, and 3, and indicated by the number 6, whilst the result of Lander's experiments on drawn- steel pipe is indicated by the number 10, the abscissae being values of log. and the ordinates values of — . In fig. 4 the same equations v v2 / vs \ vcl are plotted in terms of log. (— — b) and log. — . Line 6 represents Stanton's experiments, and line 10 Lander's. These two lines converge at or near to a point 0, where the motion changes from linear to sinuous. Line 12 represents linear flow, and should be common to all pipes within limits. The convergence of these three lines indicates that the two pipes fulfil the condition as regards geometric similarity. The method of plotting adopted in fig. 4 affords a ready means of determining the characteristic of any description of surface, provided that the condition before mentioned is fulfilled, for it is only necessary to make one observation of the quantities involved and to join the point representing the observed value to the point 0 in order to determine the whole characteristic. There is one remarkable coincidence between Stanton's and Lander's results — viz., the ratio of a to b is the same in both ; which suggests a possible relationship which would be most useful if it can be proved to have any dynamical significance, but no deduction can be made in the absence of such a proof. In applying the principle involved in equation (2) to experiments upon large pipes we encounter several elements of uncertainty. One is that the temperature of the water has not, as a rule, been observed and recorded ; but as the error involved in assuming a uniform tempera- ture and applying it to all the experiments is considerably less than the error arising out of other disturbing factors, and probably less than the error of observation under the conditions prevailing during the experiments, the temperature error is of no great moment. Another factor which affects the harmony of the results arises from the fact, that large-diameter pipe lengths are shorter than small-diameter pipes, and that in consequence the joints are more frequent ; and, as the joint is a disturbing element, a large pipe and a small pipe of the same material and surface — such, for instance, as cast iron — are not strictly comparable on account of the increase in the number of joints, and often also because of the different nature of the joint. There is also the possibility that in two experiments on pipes of the same size and material the joint of the one may be better made than that of the other, and greater care taken in aligning the pipes. In the case of riveted steel pipes we have still other disturbing factors. The longitudinal joints ma\ be lapped or butted. There may be one, two, or three longitudinal joints in the circumference The circumferential joints may be alternately in and out, or taper ; in neither case is the diameter of the pipe uniform. In one case we have a larger diameter alternating with a smaller diameter by twice the thickness of metal, with Parky. — Resistance to Flow of li'ater through /'/pes. 49 the plate at the joint alternately facing and not facing the stream ; in the other case we have the plate or section tapering from a large end to a small end hy twice the thickness of the plate, whilst none of the joints face the stream. There is further the disturbance arising out of the different thickness of plate used, and in comparing two riveted pipes of different diameter it will be realized that they are not similar in all respects unless the thickness of plate bears some proportion to the diameter. The same remarks apply generally to spirally riveted pipe. The principle involved demands that for the same values of vd at the same temperature the same value of shall be obtained ; but unless the v'2 frequency of jointing and the nature of the joints is the same, and unless there is a proportionality between diameter, thickness of plate, and size of rivet, it cannot be expected that the principle can be strictly applied, or that it can be proved to be applicable at all unless the characteristics mentioned are taken into account. In spite of the vast array of experiments upon pipes of different kinds, it will be found that few of them are of much assistance in the present investigation. The characteristics of the pipe are not always precisely defined. The experiments on any one set are usually not numerous enough, or, if numerous, do not cover a sufficient range. Those experiments that are at all suitable have been used in the present - paper, and a study of the diagrams will afford an indication as to the scope which should be given to further experiments. In addition to the disturbing factors arising out of the nature of the surface, and frequency and nature of the joints, the thickness of plate in riveted pipe, and riveting, there is evidently another disturbing element arising out of the elastic compression of the water and from the accelera- tion and retardation of the flow. Most of the available observations on large pipe have been obtained under working conditions, and subject to disturbances arising out of change in velocity of flow due to the operation of valves and governors. When a change in velocity of flow is made, a wave of alternate compression and expansion is set up which takes some time to die down, especially if the pipe is a long one, and it is quite possible to obtain widely conflicting results on the same pipe and for the same average flow, due to the operation of the various impulses that may be set up. Another possible source of irregularity is the occlusion of air in larger or smaller quantities due to fluctuations of pressure. This might affect the flow considerably at a given head, whilst the proximity of the gauge to a bend or to a discharge-opening has been found to vitiate the results. That some disturbances of the kind men- tioned are at work will be quite evident on contemplating the graphs showing the results, to which attention will now be drawn. Cast-ikon Pipe. A very complete list of experiments on loss of head in cast-iron pipe will be found in Barnes's work, Hydraulic Ftoiv Reviewed, including some particularly careful determinations by the said author himself, which fulfil all the requirements. The examples selected are taken from the publication mentioned. Four experiments by Darcy on clean, new, uncoated cast-iron pipes are represented by a, b, c, and k in tig. 1, the diameters varying from 02678 ft. to 16404 ft. The readings are erratic, and no conclusion can be drawn from them further than that the trend of the observations generally follows the curve for drawn-sceel pipes. The remaining experiments are upon asphalted cast-iron pipes, either 50 Transactions. Parky. — Resistance to Flow of Water through Pipes. 51 IN 6 52 Transactions. newly cleaned or new. The diameters vary from 3-333 ft. to 5-0938 ft. by four different observers and six sets of observations. All the readings are remarkably close, and form a most valuable groundwork for further investigation. There are in all forty-six observations, all within the limit of observational errors, which could be represented by a single curve. All that is required in regard to this class of surface is a number of observations between the values of log. = 6 and log. _ = 7. Even V V as they stand a curve could be drawn with a fair amount of probability as to its correctness, as the observations follow the curve for brass tube ; but, as the determination of the function is essentially an experimental one, the completion of the curve should be left to experiment. Wood-stave Pipe. Among the available experiments on wood-stave pipe, the most complete are those by Moritz." Two classes of pipe are used — viz., jointed and continuous. The frequency of joints in the former case is, however, not specified. The observations on I8in., 14 in., 12 in., 8 in. jointed pipe, and on a 55fin. by Moritz, and a 31 in. continuous by Moore, are plotted in fig. 2. It will be seen that in spite of the care exercised the results obtained on some of the pipes are somewhat erratic, due, no doubt, to the effect of impulses travelling through the water. The results as a whole are not consistent, and they do not lie near enough together to enable them to be represented to a single line, as the under- lying principle demands. Nevertheless, they do not disprove the ap- plicability of the principle, as the results are not consistent, whilst the difference between the observations on the same pipe are greater than the differences between the different pipes. Kiveted Steel Pipe. Of the numerous experiments on riveted steel pipe, but two or three are suitable for the purpose of this paper. As a rule, the range is short and the readings erratic, whilst the particulars of the pipe are not complete. One of the most complete and extensive sets of observations is that made by Marx, Wing, and Hoskinsf upon a pipe 601 ft. in diameter, the circular joints being butted, with a strap on the outside. The longitudinal joints are also butted, with a strap both inside and out. The length of pipe was 4,427 ft., with fourteen joints, and contained thirteen bends of 30 ft. radius and one of 40 ft. radius. The temperature of water is also recorded. The results are plotted in fig. 3 and marked a. On the same diagram are plotted experimental values by Herschellj on a 48 in. pipe marked b and a 36 in. pipe marked c. In each case the plates are Jin. thick and asphalted, built with alternate large and small cross-sections. All three sets of results are erratic, giving widely different values of 1/c2 vd for the same value of , and the readings on the same pipe differ more v than the difference between the pipes, so that no conclusion can be drawn as to the complete applicability of the principle involved. All that can be * E. A. Moritz, Experiments on the Flow of Water in Wood stave Pipes, Trans. Am. Soc. Civ. HJng , vol. 74, pp. 411-51, 1911. t C. D. Marx, C. B. Wing, and L. M. Hoskins, Experiments on the Flow of Water in the Six-foot Steel and Wood Pipe Line of the Pioneer Electric Power Com- pany at Ogden, Utah, Second Series, Trans. Am. Soc. Civ. Eng., vol. 44, pp. 34-54, 1900. I One Hundred and Fifteen Experiments on the Carrying-capacity of Large Riveted Metal Conduits, John Wiley and Sons, N.Y. Parry. — Resistance to Flow of Water through Pipes. 53 54 Transactions. <*> A to K. ^ ' •a ft <& c\ *4 \_ sj ^ \ \ C) \ V M \ l£ f \> \ ' ( 'F w rpf 'JUt r_ \ \ x. \ i K NS ^ <■ '• 1 H ^ C5 Parry. — Resistance to Flow of Water through Pipes. 55 gathered from contemplating them is that their general trend indicates that the law of resistance can be expressed in the form of equation (5). The observations are, however, not consistent enough among themselves, and, if they were, they do not cover a sufficiently wide range to enable a curve expressing the relation between - and to be drawn. There is V" V evidently some disturbing factor at work which seems to have a greater effect at low values of the mean velocity and low friction heads. Comparisons. Comparing the results as a whole as plotted in figs. 1, 2, and 3, it may be said that their general trend is such as to conform with the law expressed in equation (5), and that they do not disprove the wide application of the principle to comprehend both large and small diameters, provided that the surface characteristics are similar. As regards cast iron with clean, asphalted surfaces, the results of the more recent experiments are remarkably consistent and afford strong evidence in support of the theory, and it only requires a few more experiments in the proper region of exploration in order to enable a curve to be drawn for this class of surface. As regards wood-stave pipe, the available results are not consistent, and new observations are required throughout the range. As regards riveted steel pipes, none of the existing data are of much assistance, because of the wide variations between the readings. It is evident that in all the experiments some disturbing factors were operating in such a way as to vitiate the results, these making their influence felt more at low than at high velocities. More experiments extending over a wider range are required. Conclusion. The result of this investigation is not very conclusive. A beginning is, however, made in the direction of applying a principle which has been found to be applicable throughout a wide range of values of vd, and for widely different fluids, such as water, air, and steam, and extending it to large pipes in commercial use ; and before further progress can be made more experiments are required on pipes of different diameters and different surface characteristics, selected with a view to extending the range of observations already obtained. Whether or not this theory is applicable under all conditions, there is considerable advantage to be derived from plotting the results of observations against — , as by this means one is able to exercise a far V greater degree of judgment in selecting a probable value of c than by studying all the literature on the subject which exists, and the method is to be recommended on this account. Eeaders are referred to a previous paper, ;:: printed in the Transactions of the New Zealand Institute, for a diagram representing the coefficient of viscosity and the coefficient of kinematic viscosity of water at different temperatures, and also a diagram showing the relation between the values of log. - and vd for water at temperatures 0, 10, 20, and 30 degrees V centigrade, the use of which will facilitate the manipulation of the diagrams presented in this paper. * E. Parry, Resistance to the Flow of Fluids through Pipes, Trans. N.Z. Inst., vol. 48, pp. 487-88, 1916. 56 Transactions. Art. III. Revision of the Cirripedia of New Zealand. By L. S. Jennings, B.A.3 M.Sc. Communicated by Dr. Charles Chilton. [Bead before, the Philosophical Institute of Canterbury, ■'>tli December, 1917 ; received by Edit rs, 31st December. 1917 : issued separately, 24th May, 1918.] Introductory Note. The late Captain L. S. Jennings commenced the study of the New Zealand Cirripedia, a group of animals that had received very little attention from local naturalists, in 1910, and, becoming greatly interested in the subject, he continued his observations with much enthusiasm and great thoroughness, and hoped to be able to prepare a comprehensive paper dealing with the whole group. In 1915 he published a paper on the " Pedunculate Cirripedia of New Zealand and Neighbouring Islands " (Trans. N.Z. Inst., vol. 47, p. 285). In this he gave a revised list of the species known to occur in the New Zealand region, established a new variety of Lepas anatifera Linn., and gave a critical discussion of the specific characters of Lepas anatifera Linn, and of the New Zealand species Pollicipes. He had nearly completed his examination of the sessile Cirripedia when he left for the front, and before his departure he gave into my charge all his specimens and manuscript notes. Though nearly all the essential work of identifying the species had been done, the manuscript was not arranged in a form suitable for publica- tion. Mrs. Jennings has carefully gone over the collection, under my super- vision, and has put the notes in order for publication. The paper contains a list of the New Zealand species examined by Captain Jennings, with localities, &c, of the different species. References have been added to Pilsbry's " Sessile Barnacles (Cirripedia) contained in the Collections of the U.S. National Museum" (1916*), and to Borradaile's " Report on the Cirripedia of the ' Terra Nova ' Antarctic Expedition " (1916 and 1917) — works which Captain Jennings had no oppor- tunity of seeing. In the list given below only those species are included which had been examined by Captain Jennings. Additional species are recorded from New Zealand by Hutton (1879, p. 330), Filhol (1885, p. 485), and Borradaile (1916, p. 128). Those references only have been given which appear necessary for New Zealand workers. The collection has been named and arranged in order, and is stored in the Biological Laboratory of Canterbury College. It contains a few speci- mens added after Captain Jennings left New Zealand, mainly from the collections of Mr. W. R. B. Oliver. Captain Jennings was killed in action in France on the 15th September, 1916. By his death New Zealand was deprived of one of the most promising of the younger generation of workers in science. Chas. Chilton. * The references are made by the year of publication to the bibliographical list on p. 63 Jennings. — Bevision of the Cirripedia of New Zealand. 57 Family LEPADIDAK Lepas anatifera Linnaeus. Lepas anatifera Linnaeus, 1758, Systema Naturae, 10th ed., p. 668 ; Darwin. 1851, p. 73 ; Gravel, 1905, p. 108 ; Pilsbrv, 1907, p. 79 ; Chilton, 1911a, p. 571; L. S. Jennings, 1915, 'pp. 285, 288, figs. 1 {a, b, c), 2. Specific Diagnosis. — " Valves smooth, or delicately striated. Right- hand scutum alone furnished with internal umbonal tooth : uppermost part of peduncle dark-coloured. Filaments, two on each side." (Darwin.) Var. (a). " Scuta and terga with one or more diagonal lines of dark greenish-brown, square, slightly depressed marks." (Darwin.) Var. (b). " Carina strongly barbed." (Darwin.) Var. (c).* ;l No trace of an umbonal tooth on either scutum. The carina is not barbed and square patches on the capitulum are not visible." (Jennings.) Localities. — General type : Sunday Island, Kermadecs (Bell and W. R. B. Oliver). Locality unknown — Specimens in Canterbury Museum. Var. (b) : Sunday Island, Kermadecs (W. R. B. Oliver). Var. (c) : Chatham Islands (Miss S. D. Stand) ; hull of " Terra Nova," Lyttelton (C. Chilton) ; Waitakerei River, washed up on beach (W. R. B. Oliver). Lepas hillii Leach. Pentalasmis hillii Leach, 1818, Tuckey's Congo Exped., p. 413. Lepas hillii Darwin, 1851, p. 77, pi. i, fig. 2; Gravel, 1905, p. 110, figs. 124. 125 ; Pilsbrv, 1907, p. 80, pi. viii, figs. 2, 7 ; Jennings, 1915, p. 287. Specific Diagnosis.— " Valves smooth : scuta destitute of internal um- bonal teeth ; carina standing a little separate from the other valves, with the fork not close to the basal margin of the scuta ; uppermost part of the peduncle either pale or orange coloured. Filaments three on each side." (Darwin.) Locality. —Hull of " Terra Nova," Lyttelton Harbour (C. Chilton). Lepas pectinata Spengler. Lepas pectinata Spengler, 1793, Shifter Naturhist. Selbshabet, 2 B., 2 H., Tab. x, fig. 2 ; Darwin, 1851, p. 85, pi. i, figs. 3, 3a ; Hutton, 1878, p. 329 ; Gravel, 1905, p. 107, fig. 119 ; Pilsbry, 1907, p. 81, pi. viii, figs. 4-8 ; Chilton, 1911a, p. 571 ; Jennings, 1915, p. 286 ; Borradaile, 1916, p. 131. Specific Diagnosis. — " Valves thin, coarsely furrowed, often pectinated. Scuta with a prominent ridge extending, from the umbo to the apex, close to the occludent margin ; fork of the carina with the prongs diverging at an angle of from 135° to 180°. Filaments absent, or only one on each side." (Darwin.) Var. (a). ' Upper part of the terga (bounded by the two occludent margins) produced and sharp ; surface of all the valves often coarsely pectinated, and with the carina barbed." (Darwin.) *This variety has been described as a new species by Borradaile, under the name L. affinis (see Borradaile, 1916, p. 131, and 1917, p. 229).— C. C. 58 Transactions. Localities. General type : Chatham Islands (A. Dendy). Var. (a) : Kermadec Islands (W. R. B. Oliver) ; Waitakerei River, washed up on beach (W. R. B. Oliver) ; off Three Kings Islands (L. A Borradaile). Lepas australis Darwin. Lepas australis Darwin, 1851. p. 89, pi. i, fig. 5 ; Hutton, 1879, p. 329 : Gravel, 1905. p. 109, fig. 122 ; L. S. Jennings, 1915, p. 285. Specific Diagnosis. — " Valves smooth, thin, brittle ; scuta with internal umbonal teeth on both sides. Carina with upper part broad, flat ; much constricted above the fork, which has wide, flat, thin, pointed prongs, with the intermediate rim not reflexed. Filaments two on each side." (Darwin.) Localities. — New Plymouth beach (Mrs. B. D. Jennings) ; Sumner (A. F. Barrell) ; New Brighton (G. E. Archey and L. S. Jennings) ; hull of •' Terra Nova." Lyttelton Harbour (C. Chilton) ; Cape Campbell (T. Mc Alpine). Lepas fascicularis Ellis and Solan der. Lepas fasciculari* Ellis and Solander, 1786, Zoophytes, Tab. xv, fig. 5 ; Darwin. 1851, p. 92, pi. i, fig. 6 ; Hutton, 1879, p. 329 ; Gravel, 1905, p. 105, fig. 116 ; Pilsbry, 1907, p. 81, pi. ix, fig. 6 ; Chilton, 1911a, p. 572 ; Jennings, 1915, p. 286. Specific Diagnosis. — " Valves smooth, thin, transparent ; carina rect- angularly bent, with the lower part expanded into a flat oblong disc. Filaments, five on each side ; segments of the three posterior cirri with triangular brushes of spines."' (Darwin.) Localities. — New Brighton (A. Dendy) ; Sunday Island, Kermadecs (W. R. B. Oliver) ; Waitakerei River, washed tip on beach (W. R. B. Oliver). Lepas denticulata Gruvel, 1900. Lepas denticulata Gruvel, 1905, p. 106, fig. 118; Chilton, 1911a, p. 571 ; Jennings, 1915, p. 286. Specific Diagnosis. — *w Capitulum avec cinq plaques tres serrees, de couleur tres blanche et fortement pectinees. Carene terminee en fourche a sa partie inferieure, chacune des branches portant, du cote pedonculaire, deux pointes saillantes, l'interne plus longue que l'externe ; crete mediane dorsale avex quatre fortes dents et une serie de plus petites entre les premieres. Bord occluseur des scuta, convexe et fortement saillant an- terieurement. Une dent a Tangle umbonal interne du scutum gauche. Rien a droite. Pas d'appendices filamenteux." (Gruvel.) Locality. — Kermadecs (Captain Bollons, 1907). Conchoderma auritum (Linnaeus). Lspas aurita Linnaeus, 1767, Systema Naturae, ed. 12, p. 1110. Conchoderm-a aurita Darwin, 1851, p. 141, pi. iii, fig. 4 ; Chilton, 1911c, p. 132 ; Jennings, 1915, p. 287. Conchoderma auritum, Gruvel, 1905, p. 144, fig. 167 ; Pilsbry, 1907, p. 99, pi. ix, fig. 2 ; Pilsbry, 1909, p. 71, pi. viii, figs. 5, 6, 7; Borradaile, 1916, p. 132, and 1917, p. 230. Jennings. — Revision of the Cirripedia of New Zealand. 59 Specific Diagnosis. — " Capitulum with two tubular ear-like appendages, seated behind the rudimentary and often absent terga ; scuta bilobed ; carina absent, or quite rudimentary ; peduncle long, distinctly separated from the capitulum."' (Darwin.) Localities. — Hull of " Terra Nova," Lyttelton (C. Chilton) ; from Mega- ptera nodosa in the Bay of Islands and off Cape Brett (L. A. Borradaile) ; on whales (specimens in Otago and Auckland Museums). Conchoderma virgatum (Spengler). Lepas virgata Spengler, 1790, Shifter Naturhist. Selbskabet, B. ] , Tab. vi, fig. 9. Conchoderma virgata Darwin, 1851, p. 146, pi. iii, fig. 2; pi. ix, fig. 4: Chilton, 1911c, p. 132: Jennings, 1915, p. 287. Conchoderma virgatum Gruvel, 1905, p. 144, fig. 168 ; Pilsbry, 1907, p. 99, pi. ix, fig. 1 ; Borradaile, 1917, p. 230. Specific Diagnosis. — " Scuta three - lobed : terga concave internally, with their apices slightly curved inwards : carina moderately developed, slightly curved : peduncle blending into the capitulum.'' (Darwin.) Localities.— -Hull of " Terra Nova," Lyttelton Harbour (C. Chilton) ; ship's hull, Dunedin (specimens in Otago Museum). Scalpellum villosum (Leach). Scalpellum villosum Leach, 1824, Encyclop. Brit. Suppl., vol. iii, pi. lvii ; Darwin. 1851, p. 274, pi. vi, fig. 8 ; Hutton, 1879, p. 329 ; Gruvel, 1905, p. 33, fig. 32 ; Pilsbrv, 1907, p. 9 ; Jennings, 1915, p. 286. Specific Diagnosis. - ■' Capitulum with fourteen valves : sub-rostrum present : carina nearly straight : three pair of latera ; upper latera tri- angular. Mandibles with four teeth, of which the second is the smallest : maxillae with a projection near the inferior angle : no caudal appendage. :' Complemental male attached externally between the scuta, below the adductor muscle ; pedunculated ; capitulum formed of six valves, with the carina not descending much below the basal angles of the terga : mouth and cirri prehensile." (Darwin.) Localities. — Stewart Island (W. R. B. Oliver) ; Port Robinson (J. R. Wilkinson) ; Godley Head (W. R. B. Oliver) ; Cheltenham Beach, Auck- land (W. R. B. Oliver) ; Oamaru (L. S. Jennings). Scalpellum spinosum Annandale. Scalpellum sjrinosum Annandale, 1911, p. 164, figs. 1-4 ; Chilton, 1911b, p. 311 ; Jennings, 1915, p. 286. Specific Diagnosis. — Capitulum broad, fifteen smooth pinkish valves present, covered with a minutely hairy translucent brownish membrane. Terga large, lozenge - shaped ; scuta broadly triangular. Carina short, nearly straight, ridged dorsally but not laterally. Upper latera narrowly triangular. Rostrum, latera of the basal whorl, and subcarina prominent, pointed, spine-like. (Abridged from Annandale.) Localities. — Farewell Spit, Nelson (W. B. Benham) ; " Nora Niven " Expedition, Station 5, off Stewart Island. 60 Transactions. Pollicipes* spinosus (Quoy and Gaimard). Anatifa spinosa Quoy and Gaimard, Voyage de V Astrolabe, pi. xciii, fig. 17. Pollicipes spinosus Darwin. 1851, p. 324, pi. vii, fig. 4 ; Hutton, 1879, p. 329 ; Gruvel, 1905, p. 20, fig. 24 ; Jennings, 1915, pp. 286, 291, figs. 3a, 36. Pollicipes sertus Darwin, 1851, p. 327, pi. vii, fig. 5 ; Gruvel, 1905, p. 22, fig. 25 ; Jennings, 1915, pp. 286, 291. Pollicipes darwini Hutton, 1879. p. 329 ; Gruvel, 1905, p. 21 ; Jennings, 1915, pp. 286, 291. Specific Diagnosis.— " Capitulum with one or more whorls of valves under the rostrum : upper pair of latera only slightly larger than lower latera : membrane covering the valves (when dried) light yellowish-brown : scales of the peduncle of unequal sizes, unsymmetrical, arranged in rather distant whorls." (Darwin.) Localities. — Kaikoura (collector unknown) ; Port Pegasus, Stewart Island (collector unknown) ; Russell, Bay of Islands (W. R. B. Oliver) ; Tauranga (W. R. B. Oliver) ; Godley Heads (W. R. B. Oliver) ; Stewart Island (W. Traill) ; Kaikoura (L. S. Jennings) ; Oamaru (L. S. Jennings) ; St. Clair, Dunedin (L. S. Jennings) ; Taylor's Mistake, Banks Peninsula (L. S. Jennings). The reasons for considering P. sertus Darwin and P. darwini Hutton to be synonyms of P. spinosus Quoy and Gaimard have already been fully discussed. (See Trans. N.Z. Inst., vol. 47, p. 291, 1915.) Family BALANIDAE. Balanus tintinnabulum (Linnaeus). Lepas tintinnabulum Linnaeus, 1758, Systema Naturae, ed. 10, p. 668. Balanus tintinnabulum Darwin, 1854, p. 194, pi. i, figs, a-l; pi. ii, figs, la-lo: Gruvel, 1905, p'. 211, figs. 230-33: Pilsbrv, 1916, p. 54. Specific Diagnosis. — " Shell varying from pink to blackish-purple, often striped and ribbed longitudinally : orifice generally entire, sometimes toothed. Scutum with the articular ridge broad and reflexed. Tergum with the basal margin generally forming a straight line on opposite sides of the spur." ' Var. (8) concinnus : Globulo-eonical ; walls finely ribbed : dull purple, tinged and freckled with white ; scutum, with a broad, hooked, articular ridge, with an extremely sharp plate-like adductor ridge, and with a cavity, bordered by a plate, for the rostral depressor muscle." (Darwin.) Locality. — Hull of tk Terra Nova," Lyttelton Harbour (C. Chilton). Balanus decorus Darwin. Balanus decorus Darwin, 1854, p. 212, pi. 2. figs. 6a, 66 ; Gruvel, 1905, p. 214; Chilton, 1909, p. 670, and 1911, p. 311. pi. 58. figs. 1-3 ; Pilsbry, 1916, pp. 53, 77. Specific Diagnosis. — " Parietes pale pink ; radii rather darker. Scutum with a small articular ridge. Tergum with longitudinal furrow very shallow and open ; basal margin on both sides sloping towards the spur." (Darwin.) Localities. — British Museum, from New Zealand (type) ; New Brighton * In accordance with the rules of priority, Pilsbry uses the generic name Mitella in place of Pollicipes (see Pilsbry, 1907, p. 4. and 1911, p. 33).— C. < '. Jennings. — Revision of the Girri/pedia of New Zealand. 61 Beach (L. S. Jennings) ; Wanganui (S. H. Drew) ; Chatham Islands (Dr. E. Kershner) ; Auckland Islands (C. Chilton). Bv the " Nora Niven " Trawling Expedition this species was taken at several localities on the New Zealand coast, many of them growing on the carapace of Paramithrax longicornis Thomson, with which crab the cirripede seems to be specially associated. Balanus trigonus Darwin. Balanus trigonus Darwin, 1854, p. 223, pi. 3, tigs. ~ * y^Alapenape Beach "^S tcrnyJiliris t Boundary CreeTi IWazfxxmi /t. 4, p. 260, 1906. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 71 which have an origin quite distinct from the true phosphatic nodules referred to previously. The nodular limestone, though easily recognized in the hand- specimen, differs little from the true nodules under the microscope, except that it is less glauconitic and approaches very closely to normal Amuri limestone. There can be no doubt that for a considerable. period the lime- stone formed the ocean-floor (as is indicated by the phosphatic nodules), and that it was honeycombed by the borings and burrows of marine organisms operating at that depth, and that the additional phosphatic material was obtained from the ordinary limestone by a process of concen- tration, and from remains of those organisms responsible for the burrows. It is quite intelligible that during a period of halt in the deposition the solvent action of sea-water would cause a disappearance of a portion of the floor, and, as the phosphatic material is less soluble than the calcareous, some concentration of the phosphate would result. This idea finds strong support in the following partial analyses of speci- mens obtained at Weka Pass. At this particular section the Amuri lime- stone is seen to be perforated to a depth of 4 ft. 6 in., the cavities being filled with the calcareous greensand that represents the overlying Weka Pass stone at this locality. The upper 18 in. of the Amuri limestone is much honeycombed with burrows, and completely detached fragments are to be found lying within the Weka Pass stone as much as 6 in. above the present surface of the Amuri limestone. It is to be understood that we look upon these nodular fragments as remnants of the original upper portion of the Amuri limestone which, during a halt in the deposition, was broken down by the combined action of boring-animals and solution by sea-water, some at least of the phosphate so set free being concentrated in the residual portions of limestone. Table IV. (1.) Insoluble in acid . . . . 12-08 CaO .. .. 48-65 P205 0-16 (1.) Sample 2 ft. from present surface of Amuri limestone. (2.) Sample from upper 6 in. of honeycombed portion of Amuri lime- stone. (3.) Detached nodules of Amuri limestone lying in the Weka Pass stone a few inches above the present surface of the Amuri limestone. (4.) Lower 2 ft. of Weka Pass stone. In both types of nodules fehere is little difference from the associated limestone in the character of the Foraminifera and general structure of the rock, and they seem to have been formed under similar conditions. The description applies to specimens from Amuri Bluff and Stonyhurst equally with those from Weka Pass. Under the microscope the material that fills the borings appears to be composed of much the same material as the associated limestone, and resembles in texture the Amuri limestone rather than the Weka Pass stone. There is, however, more granular glauconite, and there are more numerous shreds of mica and fragments of quartz. The glauconite does not fill the cavities in the Foraminifera so markedly, though undoubtedly some are filled. The genera of Foraminifera appear to be the same as in the Amuri limestone, Globigerina, Nodosaria, and Rotalia being clearly recognizable. (2.) (3.) (4.) 11-95 11-52 55-68 42-20 44-85 0-45 4-09 1-34 72 Transactions. Weka Pass Stone. In the typical locality near Weka Pass this rock consists of an aren- aceous, glauconitic limestone. In its lower portion the rock presents the facies of a calcareous greensand of very fine grain, with a comparatively low percentage of calcium carbonate, but this percentage increases in the higher levels. (See analyses.) Specks of glauconite are, however, distri- buted throughout the rock. It breaks at times into quadrangular blocks, but rarely with the tily arrangement which characterizes Amuri limestone, though at times there is considerable similarity between the two rocks. Under the microscope it appears to be composed largely of Foraminifera, notably Globigerina, with a considerable amount of quartz and occasional shreds of biotite. The glauconite exists as grains, sometimes as a stain on the quartz, and occasionally filling the cavities of Foraminifera. As com- pared with Amuri limestone it is coarser in texture, more glauconitic and arenaceous ; but the Foraminifera appear to be the same, and, as in the former case, have their cavities filled with calcareous material. The depth at which deposition took place would in all probability be slightly shallower than that at which the Amuri limestone was laid down. Away from the typical locality the rock exhibits considerable variation. It is sometimes more glauconitic, and in fact passes into a calcareous green- sand ; while in other places it becomes more sandy and friable. The former of these two facies represents in all probability a deposit either in shallower water or nearer a shore-line, but there is no doubt as to its equivalence to the more calcareous rock. It is perhaps not truly synchronous, in that it may mean the gradual extension of the deposit into shallower water as physical conditions in the area changed ; but the stratigraphical position and the relationship of the two facies to the underlying Amuri limestone are practically identical. Table V.- Analyses of Weka Pass Stone. (1-) (2.) SiO, . . 34-95 22-51 Al903 . m 6-44 3-92 Fe203 . , . . . 2-76 2-08 C0CO3 , . . 47-62 67-60 MgC03 . . 1-46 0-80 CaO , , , 1-50 0'-80 p2o5 n.d. n.d Organic n latter an< I water . 3-50 2-29 (1.) Weka Pass stone 2 ft. above Amuri* limestone. (Coll. J. Park.) (2.) Weka Pass stone, average sample " from Waikari end of Weka Pass, from cliffs N.E. of stream a few chains above the railway viaduct." (Coll. J. Park.) Historical Summary. The following is a summary of the opinions held by the authors cited in the bibliography at the end of the paper, in the order of time in which they are expressed : — Hector says (1869, p. xii), " The above (3 and 4) [grey marl] rest uncon- formably on blue and grey marly sandstone, sometimes passing into chalk, the formation resembling, in mineral character, the English chalk marl. In the same formation, farther north, flints occur." There is some doubt Speight and Wild. — Weka Pass Stone and Amuri /limestone. 73 concerning the proper interpretation of the beds as detailed by Hector, but the record of cup-shaped Bryozoa as occuri ing in (4) evidently points to what is called the grey marl in the Waipara section, and the beds with flints to the Amuri limestone, and the grey marly sandstone to the Weka Pass stone. It is evident, therefore, that Hector did not recognize an unconformity within the beds indicated above. Haast evidently considered the two beds of limestone as quite conform- able. He says (1879, p. 297), " In some localities a break seems to occur between the upper and lower calcareous series, as, for instance, in the Weka Pass ranges, where the lower, more calcareous strata are sometimes separated from the glauconitic massive upper beds by a small band of greensand con- taining concretions of a more calcareous nature. However, in many other localities this small bed does not occur, and the boundary between the two series is either gradual or sharpy defined. Moreover, the upper beds are found to be always conformable upon the lower where the latter exists, being, in fact, a continuation of the same series, and, owing to the sinking of the land, of greater horizontal extent than the more calcareous beds underlying them." We have quoted this description in full as it appears to us to explain concisely the whole case. Hutton (1877, 1885, 1888) always maintained the unconformable relation- ship between the Amuri limestone and the Weka Pass stone, urging that the contact was a normal erosion-surface, and in none of his writings cited in the bibliography does he depart in the slightest from this position. McKay (1881, 1886, 1887) considered the sequence conformable. Thus it is that, among the older geologists of this country who have reported on this matter, three agree that the sequence is conformable, while one maintains the contrary. We come now to the opinions of those of a more modern date. The first to be considered is that of Professor Park, who forms a kind of link with the older geologists. His views are by no means certain, and exhibit considerable evolutionary development. In his report published in 1888 he says, "As a result of the examination of many of the magnificent sections between the Weka Pass and the Waipara, I am strongly of the opinion that a complete sequence of beds exists from the base of the Cretaceo-Tertiary to the close of the Pareora formation, although the varying character of the deposits and their fossil remains show that the sea-bottom on which they were deposited was subject to frequent oscillation." Again (1905, p. 546), he says, " Captain Hutton contends that there is an unconformity between the Weka Pass stone and the Amuri limestone. I have carefully examined the line of contact of the two rocks, but was unable to find any evidence of unconformity ; and on this point my view coincides with that of Sir James Hector, Sir Julius von Haast, and Mr. McKay." In his Geology of New Zealand (1910) Park evidently regards the two limestones as conformable, a position which he maintained in 1911 (p. 546). Next year, however, as a result of the finding of Pecten huttoni in the Weka Pass stone, he moved his unconformity to the base of the Weka Pass stone, which he then stated lay conformably under the Mount Brown limestone, although he had in 1888 demonstrated on stratigraphical grounds the existence of an unconformity between them. His position, therefore, seems somewhat obscure. Marshall (1911, 1912) has always maintained the physical conformity between the beds of this series, and in this he has been supported by Cotton and Speight, both in conjunction with him (1911) and independently (1912). 74 Transactions. Thomson also (1912, p. 8) has noted the physical conformity of the beds in the typical locality, whereas Morgan (1915, pp. 90-93), the latest writer on the subject, as a result of a hurried visit came to the conclusion that the top of the Amuri limestone presented a true erosion surface, but as the result of more complete examination of the relationship of the beds expresses himself in a less dogmatic manner (1916, pp. 17-28, and 1916a, pp. 10—11), and has evidently some doubts as to the correctness of his first interpretation, although he still agrees tentatively with Hutton and Park in his latest pronouncement. Detailed Descriptions of Important Sections. In order to arrive at a thorough appreciation of the problem a detailed description will be given of all localities where contacts occur from the neighbourhood of Mount Grey to just north of Kaikoura, and from the sea-coast as far inland as limestones occur which furnish any evidence. This ranges over a belt of country nearly one hundred miles in length and with a maximum breadth of fifteen miles. The localities first taken are those in the neighbourhood of Weka Pass, the typical locality ; then those near the Waipara River and Mount Grey. They are followed north-east to Cheviot, when a return is made along the coast by way of the Hurunui mouth, Stonyhurst, and Motunau ; and the series concludes with those at Amuri Bluff, Kaikoura, and the Puhipuhi River. We do not think that any important locality in that area has been omitted from consideration. It will be noticed that there is a general similarity of the sections throughout the area, both in its length and its breadth, which the advocates of uncon- formity will find difficult to explain, while the evidence for conformity is particularly strong. Weka Pass. Good contacts can be seen at various places in the neighbourhood of the pass — e.g., on the roadside just past Seal Rock, in the little gorge near the viaduct, on the northern face of the escarpment just east of the viaduct, and on both sides of the denuded anticline to the west of the viaduct. (Plates IV and V.) The following description fits in each case : — (1.) Amuri limestone: White, and jointed into flaky quadrangular blocks, the upper 2 ft. or more being bored by marine worms and the casts filled with glauconitic limestone. The amount of boring increases progressively upward till what may be called the transitional layer is reached. (2.) Transitional layer : This consists in its lower part of Amuri lime- stone material thoroughly bored, with the interstices filled with glauconitic limestone. The result of boring increases progressively, and the quantity of glauconitic material also increases pari passu. The upper 6 in. is com- pletely bored, so that peninsulas of Amuri limestone project at times into i he overlying glauconitic layer, and at times become detached and resemble subangular pebbles in appearance. They are more phosphatic than the underlying limestones, and the included glauconitic limestone is more phosphatic than the overlying glauconitic layer. The number of residual fragments of limestone decreases till they are entirely absent from the distinct layer of strongly glauconitic limestone. Included in this band are small angular nodules, green or black in colour, which are strongly phosphatic. Very occasionally, small well-rounded pebbles of quartz, about I in. in diameter, are met with. Trans. N.Z. Inst., Vol. L. Plate IV. .9 a, CO O o 3 9 co «,* O (D -9> J 0) 0.9 -+^> co CO rQ CO £ CO O c8 ^ ^ 9 »i _ m CD - O o 9 o O Face p. 74.] Trans. N.Z. Inst., Vol. L. Plate V. o .^ ♦ V / . ' .'■• I tft ^f 02 O bfl ID Q Ph 03 O « W d -Q o c c c w £.5 a o c O o Speight and Wild. — Weka Pass Stone and Amuri Limestone. 75 (3.) Glauconitic calcareous sandstone : This is a distinct layer, about 6 in. thick, of strongly glauconitic fine-grained calcareous sandstone, which passes up into Weka Pass stone. (4.) Weka Pass stone: This is a distinctly glauconitic, arenaceous lime- stone. The green and black nodules which mark the contact appear to diminish in number on going south-west along the escarpment, but they are occasionally present and so mark a continuous horizon ; but on approach- ing the Waipara River the difference between typical Amuri limestone and Weka Pass stone disappears, and the contact becomes indefinite — in fact, the two beds merge into one limestone without any break. Main Branch of Weka Creek. There is an excellent exposure of the contact in the branch of the Weka Creek north-west of the main road, just where it is crossed by the subsidiary road running from Weka Pass behind the Mount Brown escarpment in the direction of the Waipara River. The stream has in this locality cut a deep narrow gorge right across the strike, and the contacts of the Weka Pass stone with the underlying Amuri limestone as well as with the overlying grey marl are excellently shown, both being quite conformable. In the case of the former contact we have the following sequence : — (1.) Amuri limestone, breaking into quadrangular blocks, with interstitial calcareous greensand in layers parallel to the bedding in its upper portions, very occasional burrows extending to 6 ft. below the actual junction. On approaching the junction the amount of greensand becomes greater, both in layers and in burrows, till near the contact the two form nearly equal proportions in the rock. Thereafter the Amuri limestone diminishes in importance, and inclusions of limestone in the greensand become rare. Dark- green and black nodules (phosphatic) as well as ironstone con- cretions also occur. The thickness of the layer where the two occur is about 12 in. (2.) Greensand layer, without inclusions of Amuri limestone, about 1 ft. in thickness, but passing up into (3.) Weka Pass stone in its typical development. The contact between the two limestones is clearly seen on the escarp- ment to the north, and is visible at times on the south as far as a limestone knob a mile south of the creek, when for some distance towards the Waipara the junction is obscured. As far as it is visible it displays the same charac- teristic features. Upper Waipara. Excellent sections showing the relationship of the two facies of the limestone are to be seen above the limestone gorge of the Waipara River along the bold escarpment facing north-west. At the gorge itself there is the following sequence : — (1.) The marly facies of the Amuri limestone forms the lowest portion in this locality, and passes up into (2.) Typical jointed Amuri limestone with interstratified bands of argil- laceous and glauconitic limestone. The upper layer of Amuri limestone is a compact white rock containing glauconite, the upper 6 ft. or 8 ft. with a concretionary fracture and passing up into (3.) Weka Pass stone of more than usual glauconitic character. 76 Transactions. No nodules r borings are present on the line of junction, which is indistinct one rock gradually passing into the other. Along the escarpment to the south-west the same general features are to be observed, the Amuri limestone being decidedly glauconitic at times and the greensand layer at the junction more marked than near the gorge, while the Weka Pass stone exhibits in places the typical facies, though in others it is like the Amuri limestone, and in others again it is of sandy texture, approaching a freestone, and is so friable that it can be rubbed into powder with the fingers. At the point where shells of Pecten huttoni are found in the Weka Pass stone, which is a few chains east of the low part of the escarpment where the road crosses, the junction presents the usual features of worm-borings and the presence of scattered dark phosphatic nodules, while on the weathered surface of the Amuri limestone there are small protuberances of limestone, evidently more resistant than the remainder of the rock, and owing their preservation to the presence in them of an amount of calcium phosphate in excess of that in the surrounding rock. When traced west the limestone outcrop passes over into the water- shed of Boby's Creek, and in the bed of its most northerly tributary an excellent exposure is to be seen. This is as follows : — (1.) Amuri limestone, the upper 3 ft. bored more and more till the junction is reached, the borings being filled with greensand. Detached fragments of more phosphatized limestone occur along the junction. The limestone is here much thinner than it is on the escarpment to the north-east, and thins out still more when followed to the south-west towards Mount Grey. (2.) Nodular layer : This consists mostly of detached fragments of limestone, the true nodules being small ; all are enclosed in a greensand matrix. A well-rounded pebble of greywacke was found embedded near the junction, indicating in all probability the close proximity of a shore-line. This passes up into (3.) Greensand, with fewer and fewer nodules. (4.) Weka Pass stone, more glauconitic than usual, as is usually found as the deposits approach an outstanding greywacke mass ; in this case it is that of Mount Grey. In the lower part of this layer shells of Pecten huttoni were found in a somewhat poor state of preservation. The strike of all the beds is north-east and south-west, with a dip to the south-east of 35°. No evidence of unconformity, excepting the pebble, is given by this locality, although it affords ample opportunity for locating one did it exist. The interstratification of glauconitic limestone in the Amuri stone indicates that no great change in depth occurred between the deposit of the typical Amuri limestone and the Weka Pass stone, the interstratification of the glauconitic material in the former preparing the way for the final develop- ment of the pronounced glauconitic type. North-east Slope of Mount Grey. The fine escarpment which runs south-west through Mount Brown towards Mount Grey is deflected when it reaches the vicinity of the mass of greywacke of which the latter is composed, no doubt partially owing to earth-movements, of which there is decided evidence in the locality. Speight and Wild. — Weka Pass Stone and Amuri Limestone . 77 A well-defined fault-scarp runs along the eastern face of the mountain in a north-west and south-east direction in a line with the western margin of the depression which continues towards Heathstock and the Upper Waipara basin. On the western side of this, in the vicinity of Mount Mason and elsewhere, there is evidence of deformation where the limestones abut against the older rocks. This line of deformation evidently belongs to the series of north-west and south-east earth-fractures which are characteristic of the mountain region of Canterbury. As a result of this and related movements the Mount Brown beds and the underlying limestones are bent round till on the divide between Boby's Creek and Kowai Biver they strike north- west and dip to the north-east at high angles, about 70°. The edges of the beds are thus exposed, and the relations of the Amuri limestone to the beds immediately overlying it are well seen in one or two places. The sequence is here as follows : — (1.) Amuri limestone, of the usual type, well jointed, and not more than 25 ft. thick ; it thus shows the characteristic thinning- out as it approaches a shore-line. In its upper layers it is glauco- nitic, and deeply bored, with the borings filled with greensand. (2.) Nodular layer : This is about 4 ft. wide, with pieces of limestone in a matrix of greensand. This bed is closed with a fairly well- defined layer of fragments in which limestone predominates over greensand, as if there were a partial reversion to limestone con- ditions when this part of the bed was being deposited. The calcareous nodules are distinctly bored, and show a marked qualitative reaction for phosphoric acid. There are occasional small, rounded, dark-greenish nodules, up to f in. in diameter, but these are more important in the next bed. (3.) Calcareous greensand, strongly glauconitic. It appears that the Weka Pass stone takes on this decidedly glauconitic facies as it approaches a shore-line, and also the phosphatic nodules are apparently more numerous under these conditions, suggesting a resemblance to the conditions obtaining on sea-bottoms of the present day where greensands and green muds are associated with these nodules. South Branch of Omihi Creek. South-east of the Omihi Valley, and dividing its drainage area from that of the slopes facing seaward, lies the prominent limestone escarpment of the Cass, or Limestone, Bange as it is sometimes called. On its northern side there are excellent exposures of the limestones and the underlying sands and sandstones resting unconformably on the Trias-Jura beds. Owing to a fault which runs approximately north-east and south-west, with a throw of some 1,000 ft. to the north-west, the outcrops are repeated, and we thus get two sections which show the horizon of the nodular layer. They exhibit a striking difference, however. One section has a facies which shows the proximity of a shore-line, in agreement with the fact that the Trias-Jura beds are in evidence but a few hundred yards away in the direction of the rise of the beds, whereas the other section, about a mile and a quarter to the south-east, has a facies which is characteristic of deeper water. The first of these sections is well displayed near a small waterfall on the east side of the road which runs south past the shepherd's hut in the direction of the limestone escarpment. The typical Amuri limestone is here 7 8 Tra?i sac tions . absent, but it is represented stratigraphically by a strongly glauconitic lime- stone, whose glauconitic character is strongly marked in the flaky quad- rangular blocks into which the stone is divided, but more strongly still in the interstitial portions. A well-defined layer of nodules occurs in this lime- stone, the matrix being a markedly glauconitic limestone. The nodules are of two types— (1) ordinary phosphatized limestone, and (2) small dark -green nodules up to 1 in. in diameter, scattered through the nodular layer and through the next 4 ft. of the bed above. The nodular layer is not so well defined as usual, but passes gradually into the beds above and below it. Worm-borings are a feature of the occurrence, and there is an entire absence of any evidence of unconformity. The whole arrangement gives a good illustration of the modification in the character of the Amuri limestone as it approaches a shore-line, and supports the contention of some writers that greensand can be laid down in comparatively shallow water. The other type of contact showing the relations of the Amuri limestone to the Weka Pass stone can be clearly seen on the northern slope of the escarpment to the south at an elevation of between 1,600 ft. and 1,700 ft. The following is a description of the contact as seen over a considerable length of the escarpment : The Amuri limestone is from 150 ft. to 200 ft. in thickness, well stratified and jointed, divided by narrow layers of more or less marly material, in the lower part and by seams of glauconitic material in the higher part, with occasional worm-borings on the top of the hard limestone layers. These borings are filled with marly material in the lower parts and by glauconitic material in the higher parts, corresponding to the character of the layer which was being deposited while the borings were being made. Glauconitic material becomes more pronounced in the higher parts till it passes into the Weka Pass stone, which is here slightly more glauconitic than in the typical locality. The sequence is perfectly con- formable throughout, the limestones changing from the Amuri to the Weka Pass facies with characteristic passage beds in which the two types are interstratified along the line of junction. In some places it is difficult to tell the precise line of demarcation of the two. No nodules were seen. North Side of Waikari Creek between Waikari and Scargill. On the north side of this stream lies a prominent band of limestone with a west-south-west strike, dipping south -south-east. It is a remnant of a more extensive covering sheet of Tertiary sedimentaries which has been faulted into a position less exposed to destructive agents as a result of earth- movements which have affected the whole region. The main fault-line follows approximately the line of the stream-valley, but a number of sub- sidiary faults running parallel to this on its northern side are plainly in evidence in the upper basin of the Scargill Creek, where there are a number of parallel belts of limestone, generally dipping south-east, the repetition of the outcrops being directly attributable to this series of faults. The steep scarps face north-west, and they give good opportunities for examining the limestone through its whole thickness. Specially good exposures occur on the north side of the high escarpment behind the greywacke barrier which divides the Scargill basin from the Waikari Valley, and fronting the stripped surface of greywacke which separates the former from the Culverden basin. The section shows that the limestone band is composed of alternating layers of more or less glauconitic material, some of which, usually the less glauconitic, have the jointing characteristic of the Amuri limestone, while Speight and Wild. — Weka Pass Stone and Amuri TAmestone. 79 other layers have the Weka Pass stone facies. Worm-borings are found ac various levels, and very occasional nodules are sporadically distributed. Rock of similar features is to be seen on the north bank of the Waikari Creek about two miles below the Waikari Township. In this place frag- ments of whale-bone occur in rock of the Weka Pass type. There is no evidence in either of these localities of any break in the suc- cession, the whole being certainly conformable. Although there is some variation in the lithological character of the rock from that in typical locali- ties, yet there is no reason to suppose that it has not been formerly in close lateral continuity with the masses on the south side of the valley which show the typical differentiation into stone of two facies. There is just the difference that one would anticipate were the beds north of the Waikari deposited in an area in closer proximity to a shore-line than that in which the beds were deposited in the main Waipara, the Weka Pass, or the Cass Range areas. The fact that the sequence is unbroken in what appears to be a shallow-water facies, where one would anticipate breaks, supports the con- tention that the deeper- water beds are conformable. Gore Bay. An interesting locality is Gore Bay, near Cheviot, where sections are well exposed on the cliffs along the shore and on the southern side of the gorge which the Jed River has cut along the line of junction of the grey- wackes and the overlying Cretaceous and Tertiary beds. These latter are bent up into a well-marked syncline, which forms such a characteristic feature of the cliffs behind the sandhills of Gore Bay. Faulting is common, and on the southern wing of the syncline this has resulted in considerable crushing and brecciation along the belt of movement ; nevertheless the relations of the beds are clear. The Amuri limestone in its typical facies is somewhat thin in this locality — about 12 ft. ; but there is an under- lying succession of marls with interstratified sandstone which is no doubt the equivalent of the lower part of the Amuri limestone at Kaikoura and other localities farther north and in the neighbourhood of Weka Pass. The upper surface shows a characteristic junction, with phosphatic nodules, succeeded by a calcareous greensand, the probable equivalent of the Weka Pass stone. (See Hutton, 1885, p. 271, for a similar occurrence near Stony- hurst.) There is no evidence, however, of an unconformity, the sequence throughout being entirely regular. The following is a detailed description of the occurrence in a deep washout in the cliffs about a quarter of a mile north of the disused landing-stage at Port Robinson. The beds are much crushed, but their relations in the vicinity of the line of junction are clear and characteristic. (Plate VI, fig. 1.) Amuri Limestone. — The typical portion is about 12 ft. thick, but it is underlain by greyish marl. Borings begin about 3 ft. below the upper surface, but they increase in number till the contact is reached. The cavities are filled with greensand. Nodular Layer. — This is 6 in. to 8 in. thick. The nodules are in a matrix of greensand, some being of phosphatized limestone, the other more charac- teristic ones varying in colour from light green through olive-green to dark green and black. Calcareous Greensand. — This is the probable equivalent of the Weka Pass stone. It is strongly calcareous, and contains nodules sporadically up to 3 ft. above the junction. Some of these have the external appearance of greywacke but are distinctly phosphatic, and are dark green in colour. They are up to 1\ in. in diameter, but numbers of them are small. 80 Transactions. An exactly similar section occurs on the north wing of the syncline where the road comes down on to the beach near the old lime-kiln. This locality is also noteworthy since the limestone contains abundant nodules of flint. There is no evidence of unconformity. A similar junction occurs on the steep scarp facing the Jed Kiver, but farther north-west, on the south side of the road leading to Cheviot, we weie unable to locate it definitely owing to the covering of grass where the loose greensand had been removed ; but the borings in the limestone were noted in various places, so no doubt a similar contact exists there as well. South Bank of the Hurunui. On the south bank of the Hurunui, half a mile up-stream from the lowest bridge and about a mile from the sea, the whole series from the greywacke upwards is clearly exposed on the river-bluffs. The section consists of the following : — (1.) Sands. (2.) Amuri limestone, over 50 ft. thick, with a north-and-south strike, and a westerly dip of 10°. It is of the usual character, the upper 4 ft. perforated with borings, the cavities filled with greensand. Included in the limestone are lenticules of greensand, and in the uppermost 2 ft. this condition is more pronounced, typical green nodules occurring sporadically. (3.) Nodular layer : This is 6 in. in thickness, the nodules being dark green to brown in colour, up to 2 in. in diameter, subangular, the whole layer being densely compacted with greensand cement. (4.) Calcareous greensand, soft, very glauconitic, and containing nodules scattered through the lower 2 ft. (5.) Calcareous greensand, 30 ft. thick. A fragment of coal 3 in. in length and 1 in. thick, lignitic in character, was noticed in this bed. The section is closed by brown sands. Parts of the section are faulted, but where there is no evident disturbance the conformity is clearly dis- played. Especially is this the case on the river-cliffs. In a cutting on the road in close proximity water-worn pebbles of greywacke are apparently involved near the junction, but they also occur in greensand 2 ft. above the junction ; the occurrence is only a few feet in length, quite local, and, as the rocks show disturbance, may be attributed to fault or slip movements, since no similar phenomenon was observed elsewhere. On Coast South of the Blyth River. This section can be seen near the top of the magnificent limestone cliffs which form the background of the Napenape beach, one of the finest coastal scenes in New Zealand. Here old shore-platforms with beach-gravels on top occur at a height of 500 ft. The sequence exposed is as follows :— (1.) Amuri limestone: This strikes north-east, and dips south-east at low angles ; it is probably affected by slight local folding, but, owing to slipping, the precise direction is difficult to determine ; its thickness is at least 300 ft. The rock is beautifully white, compact in texture, jointed in typical fashion, but much disturbed by slips and faults owing to erosion of the shore and to natural fractures. A small mollusc shell was found in the upper layer, which has been identified by Mr. Suter as a variety of Pecten williamsoni. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 81 (2.) Greensand layer : This is loose, calcareous but strongly glauconitic, 8 ft. thick, without nodules as far as could be seen on the face of the steep cliff, and passing up into (3.) Glauconitic arenaceous limestone, 12 ft. thick, resembling Weka Pass stone but rather more sandy. (4.) Grey marl : This succeeds (3) with perfect conformity. Its thick- ness cannot be estimated, since the highest shore-platform has been cut in it. The upper layer of Amuri limestone contains borings filled with green- sand, and the marl also contains borings filled with marl. Stonyhurst, in a Creek near the Homestead. This place was visited in order to obtain observations of the section recorded by Hutton (1885, p. 271). It is unfortunate that he does not give the precise locality, but a careful examination of the creek in the neighbour- hood of the station showed that only one section in the course of the stream was possible, and a description of this is given below. Hutton's remarks are, however, very important. He says, " Here the Amuri limestone is overlain by grey sandstone, probably the representative of the Weka Pass stone. Between the two rocks is a bed of conglomerate formed by sub- angular pebbles of slate. At first sight all three appear to belong to one system, but a close inspection shows that the surface of the limestone is fissured, and that the sandstone penetrates through the conglomerate into the limestone. This, however, may be due to chemical erosion." The special importance of these remarks is that they contain a record of pebbles of greywacke along the junction ; it is extremely likely that these pebbles are phosphatic nodules, since at times the latter closely resemble greywacke in external appearance. It is unfortunate, therefore, that Hutton's precise locality cannot be determined. In the creek near the homestead the beds lie very flat, and are obscured by surface accumulations and vegetation. At one place a clear section was seen, the only one occurring in the creek. Its record is as follows : — (1.) Typical Amuri limestone, striking north-east, and dipping south- east at an angle of about 25°. (2.) Nodular layer, 6 in. thick, with the usual characters. (3.) Calcareous greensand. This passes up into (4.) Weka Pass stone of more than usually glauconitic character. The locality is disturbed by faults, but away from the disturbance the dip and strike of the Amuri and greensand limestones are identical. Motunau River. An excellent section through the whole series is to be seen in the lower course of the Motunau River, and the limestones are well exposed in its limestone gorge about two miles from the sea. The beds strike here north- north-east, and dip east-south-east at an angle of 20°, the whole being absolutely conformable. The sequence is as follows : — (1.) Amuri limestone, with typical macrostructure, its estimated thick- ness being 300 ft., the upper 4 ft. with borings filled with green- sand. (2.) Nodular layer, 3 in. to 4 in. thick, composed of subangular nodules in a matrix of greensand ; the nodules are up to 3 in. in diameter, dark-blackish-green in colour, with brown shade inside ( \ Hutton's greywacke pebbles). 82 Transactions. (3.) Greensand, 25 ft. thick with sporadic nodules in the lowest 2 ft., more thickly distributed near the junction. This passes up with occasional more marly or arenaceous layers into arenaceous lime- stone (Mount Brown limestone) ; passage beds are well developed along the junction. Boundary Creek. Boundary Creek, which lies midway between Stonyhurst and Motunau, was also examined, since McKay (1881, p. Ill) records a good section there. The exposure was found to be very unsatisfactory owing to slips, although probably it was in better condition when McKay described it nearly forty years ago. The Amuri limestone appears to be about 20 ft. thick, but the exact contact with the overlying beds is not visible at present. Large blocks of greensand also occur in the bed of the stream, showing plentiful subangular nodules similar to those in the Motunau, associated with borings filled with greensand, no doubt near the actual junction. McKay does not mention this greensand layer, and says that grey marls immediately overlie the Amuri limestone. Judging by the dip, the limestone is in a conformable position under the top beds of the series, which have a general synclinal arrangement with the eastern limb towards the present coast-line ; but there are local variations in dip well displayed on the sides of the deep gorge which the stream has cut through the non-resistant sands and marls which close the Tertiary series in this locality. It is noteworthy that McKay considers the sequence below the Motunau beds to be perfectly conformable, although he places a stratigraphical break immediately at the base of these beds, a conclusion which appears to us not warranted by observations of dip and a general examination of the section both here and in the Motunau River. The similarity of the sections in the two localities is most marked, and the evidence available from one supports that from the other. South Side of Amuri Bluff. (Plate VI, fig. 2.) The Amuri limestone is much jointed into flaky quadrangular blocks something like a tiled roof ; it strikes north-east, and dips south-east 30°. The top 4 ft. are bored through and through with tubes which are well filled with calcareous greensand, the phenomena being progressively more marked as the upper surface is reached, where the rock is completely honey- combed and the fragments are detached. These are from 1 in. to 3 in. in diameter and are also completely bored. From this level upwards the pebbles decrease in importance and the greensand increases. All through the greensand layer nodules occur, which become smaller in the upper portions ; the thickness of the greensand layer is about 2 ft., and the nodular portion where the structure is most marked is about 1 ft. thick. Above the greensand layer the rock passes gradually upward for about 3 ft. into typical Amuri limestone. The nodules of the upper layer are markedly phosphatic, while those of the lower layer are only slightly so ; the phos- phatization apparently diminishes progressively from the nodular layer. There are numerous sharks' teeth and occasional bones (? whale-bone) in the nodular layer. On Bluff North of the Mikonui Creek. The bed is exposed on the face of the cliff immediately to the north of the point where the track rises over the shoulder of the spur to escape high tides. Here we have the following sequence : First, typical Amuri Trans. N.Z. Inst., Vol. L. Plate VI. [7'. Fletcher, plwto. Fig. 1.— Contact of Amuri limestone with greensand layer containing phosphatic nodules, Port Robinson. A small fault is also apparent. [R. Speight, photu. Fig. 2. — Nodular layer in Amuri limestone, south side of Amuri Bluff. The parallelism of the layers is very marked. Face p. 82.] Trans. N.Z. Inst., Vol. L. Plate VII. [R. Speight, photo Fig. 1.— Nodular layer in Amuri limestone, Maori village, Kaikoura Peninsula. The dark, flat surface marks a fault almost parallel to the strike. / ~!f<"s^f' >-iy [iJ. Speight, photo. Fig. 2. — Nodular layer in Amuri limestone, Atiu Point, Kaikoura Peninsula. Note the parallelism of the beds. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 83 limestone, followed by greensand with inclusions of Amuri limestone, 5ft. thick in one place, and containing distinctly angular, black phosphatic pebbles. In some parts of the contact the Amuri limestone has inclusions of greensand, the latter being in relatively small amount. This is suc- ceeded by 12 in. of nodular layer of the usual type, and followed then by glauconitic limestone with small green nodules and black nodules. As the band is traced north and south from the point under consideration the greensand is not so prominent but is mixed with Amuri limestone, which is especially glauconitic on or near the junction. Near Maori Village on South Side of Kaikoura Peninsula. (Plate VII, fig. 1.) The contact is well exposed in this locality on the raised shore-platform which covers a large area on the south side of the peninsula. The follow- ing sequence in ascending order occurs here : — (1.) Amuri limestone, of the usual type, but rather more flaky than jointed, perhaps the effect of faulting. (2.) Fault, almost parallel with the strike, with a small but increasing throw when followed to the south-west. (3.) Calcareous greensand from 8 in to 10 in. thick, showing honey- combed borings filled with glauconitic limestone, together with masses of greensand of irregular form. The lower part is filled with cavities, some of the worm-bored type, while others are much larger and irregular in form, the whole being filled with a uniform type of calcareous greensand. In the upper portion the worm-casts and greensand masses are smaller. (4.) Nodular layer : The nodules are green and black, and the structure is very well developed, so that the intervening spaces are small. These are filled with calcareous greensand. (5.) Glauconitic limestone, 4 in. to 5 in. thick. (6.) Greensand, |- in. thick. (7.) Glauconitic limestone, rather more glauconitic than (5), 5 in. (8.) Greensand, 1 in. (9.) Glauconitic limestone, more glauconitic in the lower layer but passing up into one which is less glauconitic, 10 in. (10.) Limestone, of Amuri type, with flints, 6 in. (11.) Glauconitic limestone, with only a small amount of glauconite. (12.) Amuri limestone as typically developed, 120 ft. in thickness. This section shows no sign of unconformity. North of Atiu Point, East End of Kaikoura Peninsula. (Plate VII, fig. 2.) The contact is well displayed in this locality on the shore-platform at the base of the cliffs and on the cliffs themselves. The following is a description of the beds in immediate proximity to the contact : — (1.) Amuri limestone. (2.) Calcareous greensand : The rock is bored in the usual manner and the interstices filled with calcareous greensand, and becomes more glauconitic upwards, and contains nodules green in colour, irregular in shape, up to \ in. in diameter. This merges gradually into the nodular layer. (3.) Nodular layer, consisting of phosphatic nodules, more continuous than usual, the progressive development being more marked, the nodules being in a cement of calcareous greensand. (4.) Limestone, 1\ in. thick, with nodules in small number. 84 Transactions. (5.) Calcareous greensand, 2h in. thick, well bedded. (6.) Glauconitic limestone, 8 in. (7.) Greensand, 3 in. Above this there are regularly distributed layers of calcareous greensand and glauconitic limestone throughout the next 3 ft. above the nodular layer, and this is followed by (8.) Amuri limestone, with flints, the lower 10 ft. of which is bedded in layers which are more or less glauconitic, which finally passes up into typical stone striking north-west, and dipping south-west 10-15°. All the layers of this sequence are much folded, the intensity of the deformation being of the same order in each case. The same beds are seen on two other cliffs north of Atiu Point where the strata strike almost parallel to the shore-line but with acute minor folding. The nodular bed is 8 in. to 10 in. thick, with the same general features as before ; the greensand layers are, however, between thicker beds of limestone above, but underneath are the same as usual. The nodular layer also occurs on the shore-platform in this locality, but is much contorted and separated by faulting from the main layer. North Side of Kaikoura Peninsula, on the Shore-platform between the Old and New Wharves. This occurrence has not been noted previously, as it is somewhat difficult to locate. The limestone in which it occurs is much folded and contorted, but where the contact occurs the strike is north-east, and the dip south-east at an angle of 50°. The following is the sequence as here shown : — (1.) Amuri limestone, flaky in general, but subschistose occasionally owing to the movements of the beds, and with crystalline texture. The upper 6 in. of the limestone contains a considerable amount of flint, some of which contains calcareous greensand in borings, an extremely important point bearing on the origin of the flint. (2.) Nodular layer, 6 in. thick, with nodules in a glauconitic matrix but less rich in nodules than usual, and succeeded by (3.) Glauconitic limestone and calcareous greensand in alternate layers, the former 3 in. and the latter | in. in thickness. The lowest 3 ft. contain small and typical green phosphatic nodules. There- after the layers of glauconitic limestone are thicker, but still alternate with narrow bands of calcareous greensand to a depth of 20 ft. to 25 ft. It should be noted that at one spot three angular pebbles of basalt 2| in. in diameter were found. These may have been of contemporaneous origin, but more likely were embedded at a later date, as others were found loose. Mouth of Lyell Creek, Kaikoura. The contact of the typical Amuri limestone with the overlying stone of the Weka Pass facies is to be seen close to the mouth of Lyell Creek on the northern side of the Kaikoura Peninsula. It is on the western wing of the anticline which forms the main mass of the peninsula. The beds strike here east-north-east, and dip north-north-west at an angle of 20°, the agreement between the two facies of the rock being complete. The following is a description of the contact as far as it can be seen ; at the time of our visit it was unfortunately partly obscured by a covering of beach shingle. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 85 The underlying beds are of Amuri limestone as typically developed, very white, with flaky jointing and nodules and masses of flint, and with borings filled with greensand. Over this lies, with the intervening beds obscured by gravel, a glauconitic limestone, with inclusions of Amuri lime- stone which is decidedly phosphatic, the thickness being uncertain but certainly not more than 3 ft., the upper portion containing more of these than the lower part. It is succeeded without any unconformity by a much more glauconitic limestone — in fact, a greensand — from 6 in. to 8 in. thick, containing borings, and also small, dark, oxidized nodules. This is followed by a glauconitic limestone, also with nodules, which become smaller and smaller in the higher levels. The glauconitic character is very marked, with a concentration of the glauconitic material in well-defined layers ; and borings filled with more highly glauconitic material occur throughout the whole thickness of the bed. This is succeeded in about 30 ft. (?) by the ordinary type of Amuri limestone, which very occasional glauconitic layers. No flint was observed in the upper part of the limestone. The whole section is strongly reminiscent of that at Weka Pass. Puhipuhi Valley and Long Creek. The limestone up the Puhipuhi Valley and that occurring up Long- Creek on the southern side of the Hapuku River were also examined in order to see if any similar horizon occurs marked with phosphatic nodules, but with unsatisfactory results. The best exposure that was encountered was in a cutting just past the bridge over the Clinton River, a similar junction, somewhat obscured, being observed in the gorge of the Clinton River itself. The beds in this locality are much folded, and have suffered crushing as a result of folding and faulting movements, so that their strati- graphy is not clear. In the road-cutting to the north of the bridge the beds strike east-north-east, and dip north-north-west at an angle of 60°. The ordinary Amuri limestone is succeeded by layers of calcareous greensand, the layers being more or less glauconitic through about 15 ft., some being distinctly greensand. This is succeeded by hard greyish-green arenaceous limestone, well jointed, and with bands of more greenish tint running through it. It is much crumpled and faulted, and at least 70 ft. thick, and passes up into layers of more arenaceous character. This limestone is decidedly phosphatic. There is a strong similarity to the beds exposed some ten miles away at Lyell Creek, but no nodules of phosphatic nature were met with. Although they are apparently absent, it seems quite reasonable to maintain that the junction is on the same horizon. There is no evidence of unconformity. Contact op the Grey Marl with the Underlying Limestone. Although discussion of this contact is not directly connected with the principal subject of this paper, it has some bearing on the question, and therefore a description of all the contacts noted is here included. As the grey marl is easily eroded and apt to weather readily into soil, good ex- posures are rare. Those examined, however, show certain features which resemble the contact of the Amuri limestone and the Weka Pass stone, notably the bored upper surface of the limestone and the presence of detached fragments of the lower layer included in the higher, and it seems reasonable that if unconformity is demanded in one case it must also be demanded in the other. A consideration of the following sections will illustrate our contention as to similarity of evidence. 86 Transactions. Main Branch of Weka Creek. This section occurs in the main branch of Weka Creek, below the small bridge on the road from Weka Pass in the direction of the Waipara River to the north-west of the Deans Range. The junction between the Weka Pass stone and the overlying marl is well seen in the bed of the creek and on the sides of the deep but narrow gorge where the road crosses. The agreement in dip is absolute, and the contact does not show any signs of unconformity. The Weka Pass stone exhibits on its upper surface the same kind of borings which mark the contact of the two limestones, but the bored zone is narrower. This is succeeded b}r 1 ft. of slightly glauconitic sandy marl, then by 12 ft. of slightly glauconitic sandstone, passing up into sandy marl and becoming more argillaceous higher up but still preserving something of its arenaceous nature. Near Old Wharf, North Side of Kaikoura Peninsula. The upper surface of the Amuri limestone is tily in character, as at Amuri Bluff, with lenticules of grey marl included in the limestone, as also there are inclusions of limestone in the grey marl, the inclusions being more phosphatic than the limestone and marl in general, which are practically free from phosphate. The marl is decidedly glauconitic near the contact, and presents all the features of a fine-grained glauconitic sandstone, the sandy facies extending for 10 ft. or 12 ft. above the contact. The contact is conformable stratigraphically, any divergence from a normal junction being due to folding or faulting. East Side of Kaikoura Peninsula. The general strike of the beds is north-east. The Amuri limestone is much contorted, brecciated by folding, faulted, and, as a result of these structural movements, crystalline in many parts and at times subschistose in appearance. The grey marl is folded on the same lines, and sometimes included in the limestone as a result of folding. The grey marl has been subjected to just the same intensity of deformational movement as the limestone, but it exhibits the results of these movements to a much smaller •degree except at the immediate contact with the limestone, where it is subschistose in structure. The whole locality exhibits faulting, some of the major faults running north-north-east parallel to the general trend of the coast-line of the Island, but there are numerous others crossing at right angles, so that the whole locality may be described as a complex of faulted anticlinoria and synclinoria, but wherever the junction between the marl and the limestone is clear the junction is conformable. It might be noted here that Hutton's figure of the East Head (1885, p. 273) is entirely incorrect. On the south side of the peninsula, near the Maori village, the contact is of the same character as on the north side. The Amuri limestone is slightly glauconitic, becoming more so near the junction. There is a layer about 6 in. thick where the limestone and the marl are mixed, a phenomenon which is in part due to boring. The grey marl is glauconitic in its lower part for a thickness of several feet, and contains numerous fragments of whale-bone. Along the line of contact faulting is much in evidence, the faults being both normal and reversed, with a direction in general at right angles to the strike. The figure by Hutton (1885, p. 273) is evidently given under a misapprehension of the effects of faulting, the irregular line of contact being attributed by him to erosion. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 87 South Side of Amuri Bluff. In this locality the sequence is well exposed on the finely developed shore-platform on the south side of the bluff and around the coast-line as far as the mouth of the Okarahia Creek. Above the nodular layer there is about 15 ft. or so of limestone, and this is succeeded conformably by a greenish calcareous sandstone, perhaps the equivalent of the lower part of the typical grey marl, or perhaps, as is more likely, the equivalent of the Weka Pass stone. The upper portion passes into a typical marl of decidedly argillaceous character. Hutton considered that this locality furnished strong evidence of unconformity between the grey marl and the Amuri limestone, his main line of evidence being the discordance in the dip of the former as it occurs in the neighbourhood of the mouth of the Okarahia Creek and south of it with the limestone at the bluff. This apparent dis- crepancy in angle of dip is due to folding and twisting movements affecting the beds unequally in the two localities. The limestone south of the creek dips at a very high angle, and the marl is in perfect accord with this ; while when traced in a north-easterly direction towards the bluff the beds flatten out, and nowhere present any evidence of discordance. Evidence that the Series is Conformable. This detailed account of the sections taken from widely separated parts of the area gives some idea of the general nature of the contact and empha- sizes the similarity of its features. Relying entirely on the evidence of the borings in the upper surface of the Amuri limestone and the presence of detached fragments of the limestone in the greensand matrix of the nodular- layer. Hutton and Morgan came to the conclusion that it was a true erosion surface, the supposition being that the erosion took place in the vicinity of a shore-line. No palaeontological evidence was advanced by either in support of their contention as regards the two limestones, the reason being that they are both, the Amuri limestone especially, according to Hutton, almost unfossiliferous ; thus in their opinion the existence of an uncon- formity rests entirely on stratigraphical evidence. We, however, relying on stratigraphical evidence, have come to a conclusion that the sequence is conformable, the reasons for this conclusion being as follows : — 1 . In every case there is absolute agreement in the dip of the beds above and below the nodular layer. When this occurs over a region of a hun- dred miles in length by some fifteen in breadth, unconformity appears extremely doubtful. It means that a limestone has been laid down on a deep-sea bottom, the rock has become consolidated, raised above the sea, eroded, and again depressed into deep water so that another layer of calcareous material may be deposited, and all this without any variation in angle due to structural movements or to conditions of deposition over hundreds of square miles. Such a contention appears unreasonable. 2. Apart from the evidence furnished by the included fragments of limestone in the nodular layer, and the report of the occurrence of pebbles of greywacke at Stonyhurst, which can be explained as probably the result of mistaken identification, there is no evidence of erosion of the upper sur- face of Amuri limestone. On any present-day surface of Amuri limestone there are distinct irregularities, and especially is this the case on the shore- platforms where tidal channels, &c, are a marked feature, and none of these are to be seen at any part of the contact, although it is exposed for many miles in different parts of the area, not only parallel but at right angles to 88 Transactions. the present shore-line. It would be expected that they should occur some- where. Present-day shore-lines show surfaces of Amuri limestone with no similarity whatsoever to those associated with the nodular layer, even when those parts of the shore-platform are composed of nearly horizontal layers. Any change in the nature of the rocks due to folding and conse- quent induration which might be cited from the Kaikoura neighbourhood as modifying the conditions would not apply farther south, where the influence of such movements has been comparatively slight. 3. There is no true shore or shallow-water deposit of any kind over the whole area. It is certain that during the depression demanded by the unconformists, when the surface of the Amuri limestone was lowered from forming part of a land surface or a shore-line to such a level that glauconitic limestone and greensand were deposited, beach and shallow- water beds would occur in some parts of the area. Nevertheless they are absent entirely. 4. In many places is it impossible to determine the dividing plane between the two limestones, so gradual is the transition — that is, they furnish in some places no evidence of a break. In fact, as a general rule the upper and lower layers display such a similarity in their characters, notably in the presence of glauconite, that transitional forms are to be expected. 5. In the case of the borings in the upper surface of the Amuri limestone, and also those in the Weka Pass stone in contact with the grey marl, the borings are filled with the material of the overlying bed, however deep they are down below the surface. If this is a greensand the tubes are filled with oreensand, if a marl they are filled with marl. Also, there are cases of tubes in the body of the limestone which are filled with the material being laid down on the surface into which the borings were made. If, now, these borings were made on an ordinary beach or shore -platform they would be filled with beach deposit, and would not remain open till they were de- pressed to a depth at which limestone or greensand was the characteristic deposit. 6. The remarkable uniformity in the thickness of the layer over long distances appears to be inexplicable on the basis of its being a shore-line deposit, since these are notably variable both in thickness and in the nature of their constituents. The parallelism of the upper and lower surfaces of the layer is well brought out in the photographs taken from various widely separated localities where the bed is well and clearly exposed. 7. The analyses of the so-called " rolled pebbles " at the junction between the two layers (see page 71) shows that they are not ordinary detached fragments of Amuri limestone such as would be found on a beach, which should resemble the parent rock in chemical composition. They have cer- tainly been modified by agencies other than those operating on a shore-line. Morgan (1915, p. 92) cites a paper by Edward M. Kindle on " The Unconformity at the Base of the Onondaga Limestone in New York, and its Equivalent West of Buffalo";* and remarks, "This paper describes fully an unconformity not easily detected at all points by stratigraphical evidence alone." He uses it to emphasize the fact that an unconformity can occur between two limestones. But it seems to us that such contacts are by no means unlikely, since limestones of various ages form a notable feature of the rocks of the earth's crust, and the probability of a contact between two limestones as compared with that between limestone and * Journ. Geol, vol. 21, pp. 301-19, 1913. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 89 another rock of different lithological composition is in proportion as these rocks form part of the earth's crust in the locality where the limestones are being laid down. The criteria of unconformity in general, apart from the possibility of chemical erosion on the plane of contact, will be the same as between limestone and another rock. In Kindle's paper attention is drawn to the difference in dip of the two limestones in question, and to the decided surfaces of erosion of the lower limestone. The photographs that he uses to illustrate his paper are quite convincing, and show pronounced differences in the contact as compared with that between the Weka Pass and Amuri limestones, and we have seen no locality where similar pictures could be obtained from the contact of the two New Zealand rocks. For the reasons given above the authors consider that the contact between the two limestones is not due to erosion, and that after the deposit of the lower bed no emergence from the sea took place before the second limestone was deposited. Some alteration in depth or in the conditions of deposition no doubt occurred, but they were of no greater amount than that which takes place when a bed of different lithological character is laid down in a perfectly conformable sequence. It has been pointed out that both above and below the nodular layer there is an interstratification of greensand in the limestone, the deposition being conformable, which shows that slight oscillations of level or conditions took place. The phosphatic nodules are exactly analogous to those forming now on ocean-bottoms at depths of over 100 fathoms in association with greensand, and such do not form on a shore-line. Such nodules are fre- quently found in the Cretaceous limestones of Europe and America without an unconformity being demanded, although some lapse of time and change of conditions must have occurred. The phosphate nodules occurring in the Cretaceous beds of the south of England and the north of France and in Belgium usually lie at the base of the series which succeeds another after some lapse of time. In some cases, however, distinct unconformity has been demonstrated on account of the presence of pebbles and rolled fossils, the break being of more decided character and amounting to an uncon- formity, but in other cases there is no pronounced break. The association of these nodules with a bored surface seems to indicate clearly that the boring took place not on a shore-line, but on a sea-bottom formed of a soft calcareous ooze before it had consolidated and hardened into rock. The borings extend to such a depth beneath the surface that it may be doubted whether it is possible for marine organisms to tunnel such a distance into hard rock, whereas if it be admitted that the boring took place before the rock had consolidated and while it was actually in process of deposition there is no difficulty. The filling of these deep tunnels with greensand, as has been pointed out, certainly suggests boring on a sea- bottom. Although many marine organisms have the power of making burrows, it occurred to us that they were in all probability made by marine worms, and therefore we applied to Dr. Benham for his opinion on the matter. In a private letter he says, " Unfortunately we know nothing, so far as I can find out from monographs on the Polychaeta, &c, about the burrows in deep water. When the dredge is used the surface of the mud, &c, will still be disturbed ; and even if the worms are captured the walls of the bur- rows, if any, will fall in, and the burrow, of course, will be smashed. So that I find no reference at all to burrows of worms living beyond the littoral- zone area. But we may expect that if they are formed at these greater depths they, too, will be U-shaped. You ask at what depths worms live 90 Transactions. and work. Certain species have been found at as great a depth as 3.000 fathoms, though at depths below 1,000 fathoms they are much rarer than at less than 100 fathoms — that is, the great majority live along the con- tinental shelf, and especially along the littoral area." This opinion is not conclusive, but it certainly indicates that it is possible for worms to produce borings at the depth at which greensand is deposited. The statements of Cayeux (1897, pp. 431-32 and 532-33) are of interest in their bearing on this point. He shows that phosphatic nodules occur in ths chalk of France and Belgium at levels marked by change in the depth of the sea, whether this be in the direction of increasing or of lessening depth — that is, they occur at the points of inflexion of the curves indicat- ing the depths of the sea over the area at any particular time. He says (p. 431), " La production du phosphate de chaux de la base de la craie a Belemnitelles correspond a une rupture d'equilibre de la mer cretacee, phenomene dont on a maintes preuves." These are then given, and among them may be noted the hardening of the upper layer of chalk and the presence of perforations. The first of these is perhaps analogous to the hardening of the fragments in the upper layer of Amuri limestone which may be attributed to phosphatization, and the second is a most character- istic feature of its upper surface. Farther on (p. 432), he says, " La craie phosphatee du department du Nord est en relation avec un mouvement d'exhaussement qui a eu pour resultat de chasser la mer du golfe du Mons. Son existence est liee a une periode de regression de la mer pour le Nord." Of the two instances quoted, the former applies to an increase in depth of the sea and the latter to a diminution in depth. The latter in all probability is analogous to the change from Amuri limestone to calcareous greensand which characterizes the level of phosphatic nodules in the New Zealand area. Further, Cayeux considered that the accumulations of phosphatic material took place at such a distance from the shore that the change in depth of the sea did not permit of any marked variation in the character of the terrigenous material associated with the chalk. This is borne out to some extent in the area under consideration, as it has been shown that the material of the phosphate nodules is not markedly different from that of the beds with which they are associated. In any case, Cayeux does not postulate any emergence of the sea-bottom to account for phenomena which are quite analogous to those near the junction of the Amuri and Weka Pass limestones. The Peculiarities op the Junction of the Amuri Limestone and Weka Pass Stone. It must be admitted that the junction of the Amuri and Weka Pass limestones is a peculiar one and demands some special explanation, seeing that unconformity is not admitted. The irregularity of the junction in some places could be attributed to chemical erosion, and the increased amount of phosphate in the detached pieces of Amuri limestone in the nodular band supports this contention ; but it may be explained in another way, or perhaps the two explanations are not mutually exclusive. It seems to us that the so-called erosion surface has been the result of extensive boring during the interval between the deposition of the typical Amuri limestone and the upper more glauconitic part of the bed when it formed part of a sea-bottom. As a result of the complete penetration by borings the upper surface consists in places of peninsulas of limestone surrounded by green- Speight and Wild. — Weka Pass Stone and Amuri Limestone. 91 sand. In places, too, these jutting portions have been completely cut off, so that they become detached fragments. Similar occurrences can be seen at times in the estuaries which are filled with calcareous mud and have been completely honeycombed by borrowing molluscs, &c. In this way an apparent erosion surface can be formed ; but the character of the junction under consideration requires a uniformity of conditions over wide areas, and this would be obtained if the bored surface were a sea-bottom and not a shore-line. The increased phosphatization of the fragments of Amuri limestone, and perhaps of the true phosphatic nodules, might be accounted for by the decay of the bodies of the boring organisms, in addition to probable increased phosphatization owing to concentration by the dissolving-out of the more soluble calcium carbonate from the rock. The remarkable persistence of the nodules of phosphatic material at a limited level in the limestone renders them extremely useful as a datum- level for comparing the relative age of rocks in the series, and this is all the more valuable owing to the comparative absence of fossils. It may, of course, be suggested that there is more than one layer in the limestone, and that the phosphatic nodules at Kaikoura occupy a different position from those at the Weka Pass ; but the whole of the attendant circumstances of the surrounding beds renders it extremely likely that only one layer exists. If the nodules had been laid down on the bed of a deep sea, then it is likely that the sea extended all over the area in question, and their synchronous formation would be very probable indeed. Assuming that this is so, it would clearly indicate that the Weka Pass stone was the equivalent of the upper part of the Amuri limestone in the Kaikoura district and also at Amuri Bluff ; but, seeing that the lower portion of the grey marl at Kaikoura and Amuri Bluff is lithologically a calcareous greensand, it is not at all improbable, that Hutton was partly correct in correlating the Weka Pass stone with the grey marl, only that it is the lower portions of the marl that are equivalent to the upper layers of the Weka Pass stone. However, between the marl and the limestone in the Kaikoura region there is a junction which is analogous to that between the two limestones, in that the limestone immediately below the lowest layer of the grey marl is bored and sporadic phosphatic nodules occur in it. This, of course, indicates some break in time. At the Amuri Bluff the thickness of the limestone above the nodular band is reduced to 15 ft. as compared with a thickness of 100 ft. or more at Kaikoura and a great thickness as exposed on the sea-cliffs between the Oaro and Mikonui Creeks. It must be mentioned, however, that as the beds are traced along the coast south of Amuri Bluff towards the Conway River they thin out and the limestones lose their distinctive features. This certainly suggests the vicinity of a shore-line, and therefore there is no improbability that the lower part of the grey marl in that neighbour- hood, especially that part with sandy texture, may be the stratigraphical equivalent of the glauconitic facies of the Amuri limestone farther north, the sea evidently deepening in a northerly direction. It is probable that an easterly extension of the land, either continuous or in the form of islands, divided the Kaikoura part of the sea from that south of the Hurunui. The existence of such a land if it were of low relief would not, of course, negative the contention that a sea extended generally over the site of the present Kaikouras, and that the land had been base-levelled to some extent before being depressed and covered with a veneer of Tertiary sediments. But it must be clearlv understood that the shore-lines of this land must not be con- 92 Transactions. sidered as related to the present orographic features. These are, no doubt, a very late development, as demanded by McKay and by Cotton. The failure to appreciate this point thoroughly no doubt influenced Hutton, and to some extent Morgan (1916, p. 28), in attempting to fix the position of the shore-line of the Tertiary sea in that region. Since we maintain the conformity of the two limestones, and since we can suggest no other horizon where a physical break occurs in the series under consideration, our present contention involves the recognition of the stratigraphical conformity of beds in the lower part of the sequence containing Cretaceous fossils with those higher containing Tertiary fossils. (For the latest pronouncement on the Cretaceous age of the lower members of the series see Trechmann, 1917, p. 295.) In our opinion the beds with Cretaceous fossils are definitely Cretaceous, and those higher up with Tertiary forms are Tertiary. The anomaly is accounted for by the slow and continuous deposition of the beds, so that when the period of deposition commenced the time was Cretaceous, and when it closed it was Tertiary, judging by European standards of geological time. The earlier part of this period was marked by slow depression of the land, with a corresponding change in the nature of the deposits (see Speight, 1917, pp. 350-51). During the time of maximum submergence the greensands and limestones were deposited, and as the sea-bottom was raised a reversal of the order took place with slight minor oscillations. When one considers the small area of land which was probably in existence above sea-level in the vicinity of the region under consideration, the slow rate of deposition can be readily understood. Thus during this long period of submergence of the area the local fauna had time to change from a Cretaceous to a Tertiary facies. Bibliography. Cayetjx, L., 1897. Terrains sedeinentaires, Memoires de la Societe geologique du Nord, Tome IV. Cotton, C. A., 1912. Typical Sections showing the Junction of the Amuri Limestone and Weka Pass Stone at Weka Pass, Proc. N.Z. Inst., pp. 84-85. Haast, J., 1871. Rep. Geol. Explor. dur. 1870-71, pp. 15, 25. Haast, J. von, 1879. The Geology of Canterbury and Westland, p. 297-98. Hector, J., 1869. Rep. Geol. Explor. dur. 1868-69, p. xii. Hutton, F. W., 1877. Rep. Geol. Explor. dur. 1873-74. p. 27. 1885. The Geological Position of the Weka Pass Stone, Quart. Jou,rn. Geol. Soc., vol. 41, pp. 266-78. 1888. On Some Railway Cuttings in Weka Pass, Trans. N.Z. hist., vol. 20, pp. 257-63. McKay, A., 1877. Rep. Geol. Explor. dur. 1874-76, p. 36. 1881. Rep. Geol. Explor. dur. 1879-80, pp. 108-17. 1886. Rep. Geol. Explor. dur. 1885, p. 27. 1887. Rep. Geol. Explor. dur. 1886-87. pp. 74, 78. 1890. Rep. Geol. Explor. dur. 1888-89, p. 85. Marshall, P., 1911. New Zealand and Adjacent Islands, Handbuch der regionalen Geologie, pp. 22-26, 39-41. 1912. The Yoimger Rock Series in New Zealand, Geol. Mag. (n.s.), dec. 5, vol. 9, p. 314. 1916. The Younger Limestones of New Zealand, Trans. N.Z. Inst., vol. 48, pp. 87-99. 1916a. Relations between Cretaceous and Tertiary Rocks, Trans. N.Z. Inst., vol. 48, pp. 100-19. Marshall, P., Speight, R., and Cotton, C. A., 1911. The Younger Rock Series of New Zealand, Trans. N.Z. Inst., vol. 43, pp. 378-407. Morgan, P. G., 1915. Weka Pass District, North Canterbury, 9th Ann. Rep. (n.s.) N.Z. Geol. Surv., Pari. Paper C.-2, pp. 90-93. Speight and Wild. — Weka Pass Stone and Amuri Limestone. 93 Morgan, P. G., 1916. Notes on a Visit to Marlborough and North Canterbury, with Especial Reference to Unconformities post-dating the Amuri Limestone, 10th Ann. Rev. (n.s.) N.Z. Geol. Snrv., Pari. Paper C.-2b, pp. 17-28. 1916a. Record of Unconformities from Late Cretaceous to Early Miocene in New Zealand, Trans. N.Z. Inst., vol. 48, pp. 1-18. Park, J., 1888. Rep. Geol. Explor. dur. 1887-88, p. 25-35. 1905. Marine Tertiaries of O£ago and Canterbury, Trans. N.Z. Inst., vol. 38, p. 546. 1910. The Geology of New Zeala ml. — ■ — 1911. The Unconformable Relationship of the Lower Tertiaries and Upper Cretaceous of New Zealand, Geol. Hag. (n.s.), dec. 5, vol. 8, pp. 539-49. — — 1912. The Supposed Cretaceo-Tertiary Succession of New Zealand, Geol. Mag. (n.s.), dec. 5, vol. 9, p. 314. Speight, R., 1912. A Preliminary Account of the Lower Waipara Gorge, Trans. N.Z. Inst., vol. 44, p. 221. 1915. The Intermontane Basins of Canterbury, Trans. N.Z. Inst., vol. 47, p. 336. 1917. The Stratigraphy of the Tertiary Beds of the Castle Hill or Trelissick Basin, Trans. N.Z. Inst., vol. 49, pp. 321-56. Thomson, J. A., 1912. Field-work in East Marlborough and North Canterbury, 6th Ann. Rep. (n.s.) N.Z. Geol. Surv., pp. 7-9. — — 1916. The Flint-beds associated with the Amuri Limestone of Marlborough, Trans. N.Z. Inst, vol. 48, pp. 48-58. Trechmann, C. T., 1917. Cretaceous Mollusca from New Zealand, Geol. Mag. (n.s.), dec. 6, vol. 4, pp. 294-305, 337-42. Art. VI. — Structural and Glacial Features of the Hurunui Valley. By R. Speight, M.Sc, F.G.S., Curator of the Canterbury Museum. [Read before the Philosophical Institute of Canterbury, 5th December, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 24th May, 1918.] The Hurunui Valley is one about which little has been said in geological literature, though it is one of the most interesting of the main river-valleys of Canterbury, not only for its structural pecularities, but also for the glacial features of the country in the vicinity of its headwaters. The comparative neglect is perhaps due to the relative inaccessibility of its higher parts owing to the absence of roads, though before the discovery of Arthur's Pass it was the recognized route from Canterbury to Westland, while the lower portions were, till the opening of the Cheviot Settlement and the completion of the Waipara-Cheviot Railway, epiite off the main lines of communication. In 1865 Haast made a journey up the river across the island, an account of which is given in his Geology of Canterbury and Westland (1879), includ- ing a general description of the chief landscape features of the upper part of the basin. In 1871 he visited the middle Hurunui, and furnished a report (1871), in which he referred to the basin of the Mandamus, the main northern tributary of the Hurunui. Hutton (1877, pp. 34, 35; 1889) also gave some account of the locality, and dealt with the origin of the Hurunui Plains (1877, pp. 55, 56). This is practically all that has been written on the features of the main valley, except a brief reference by myself (1915, pp. 347-48) to the formation of the Waiau-Hurunui intermontane basin. Of course, there is abundant reference to the country to the north and south of the river, such as the Pahau Valley, and to the interesting stratigraphical questions connected with the Waikari and Greta Valleys, but a consideration of these is foreign to the scope of this paper. It is intended to give an account of the general geology of the basin only in so far as it is connected with its peculiar structural and glacial features. 94 Transaction a. General Topography. (See map, fig. 1.) The chief stream of the Hurunui rises in the main chain of the Southern Alps, and flows east between bush-clad mountains whose height approxi- mates between 5,000 ft. and 6,000 ft. till after a straight course of some eighteen miles it empties into Lake Sumner. This is a fine lake, seven miles long by one a half wide in its widest part, 1,724 ft. above sea-level. Thence the Hurunui flows south-east for about eight miles, and receives on the south a tributary almost as large as itself, called the South Branch, the main stream being sometimes called the North Branch. In this part of its basin are several small lakes, the most important being Lake Katrine (which is practically an indentation near the head of Lake Sumner), Lakes Taylor (1,914 ft.) and Sheppard (1,916 ft.) in a valley between the two branches, and Lake Mason in a side valley of the South Branch. Below the junction of the two main streams the valley continues for nearly three miles in a south-easterly direction between somewhat pre- cipitous mountain-sides, and then turns east and passes through a deep, narrow, picturesque gorge, locally known as Maori Gully, and believed to be the scene of an engagement between two Maori tribes in early days. tRobinson JBlythR. FAULT L//VES AXES OF FOLDING 0_0_0_0 Fig. 1. — The Hurunui Valley. The river then flows north-east for nearly ten miles through a hilly region in a narrow channel cut in the floors of detached basins and deeply incised in the ridges dividing them, till it reaches the Mandamus River. Just below the junction with this stream the direction of the main river turns through a right angle and it enters the Hurunui- Waiau basin, flowing for about ten miles through an aggraded flood-plain till it receives the Waitohi on the south. It then makes a sudden turn and runs north-east along the southern edge of the Hurunui Plain, receiving the Pahau River on the north ; but after a course of about eight miles it again breaks through a mountain barrier in a south-easterly direction and receives the Waikari River on the south and the Kaiwara Creek on the north, immediately after which it breaks through yet another mountain barrier and debouches into the Greta-Cheviot basin, across which it flows in a broad bed with terraced banks in an easterly direction till it discharges into the sea after cutting a somewhat deep gorge through a rocky bar just at its mouth. The most striking feature of its course as a whole is the peculiar zigzag direction of the reaches which characterizes the middle part of its basin. These zigzags have alternate north-west and south-east and south-west and north-east arms, and it is their special relation to the grain of the country in some places and their absence of relation in others which is peculiar. Speight. — Structural and Glacial Feature* of Hurunui Valley. 95 Basement Rocks of the Area. The characteristic basement rock of the region is a greywacke such as is typically developed in the mountains of Canterbury farther south. This is usually of the hard grey facies, but slaty greywackes also freely occur, which break down under the weathering agencies into clay and form a covering on the mountain-slopes. On these forest once became thoroughly established, but it has been largely destroyed in the higher parts of the riv«r-valley by the grass fires of settlers. The greywackes have a general north-easterly strike, with local variations. Beds of dark-red slaty shale also occur, as well as occasional outcrops of volcanic rock. Basalts and andesites occur near Lake Sumner on the Crawford Range, and there is in the Canterbury Museum a specimen from the same area marked " eurite " by Hutton. Basalt pebbles occur in the Seaward River, a tributary coming in from the south about three miles below the junction of the two branches, and similar rocks occur in position between it and the Waitohi River. The most interesting occurrence is near the Mandamus. About a mile above its junction with the main stream a massive intrusion of augite syenite occurs in the greywacke. This has a general north-easterly trend, and it appears to have the character of a sill, being approximately parallel to the dip and strike. Its thickness is more than 200 ft., and it extends over a mile in length. Associated with it are trachyte dykes, and flows of augite andesite occur in close proximity. Hutton was of the opinion that the syenite represented the core of a volcano of which the andesite was the effusive representative. But angular fragments of the syenite are found in the andesite, in some places in considerable quantity, so that the intrusion of the syenite was evidently anterior to the andesite. We have therefore, in order of time, (1) greywacke, (2) syenite, and (3) andesites. In this district, too, there are basic volcanic tuffs having in their higher levels a calcareous tufa facies passing into a true limestone; but the volcanic beds are much better developed to the north-east, in the Pahau and Culverden districts, where there are interstratifications of volcanic material between beds of limestone. The occurrence at the Mandamus points to several periods of vulcanicity, the channel opened by the syenite affording a passage for later magmas. Younger Rocks. Volcanic rocks have exerted little effect on the area covered by the river- basin, in which greywacke is now by far the most dominant member ; but at one time the lower parts of the valley were covered with a veneer of Tertiary sediments, remnants of which are still to be found. These later beds have all a north-easterly strike, so that they cut across the river at a average angle of 45°, and at present they occupy separate compartments of the valley, cut off from adjacent ones by ridges of greywacke. These isolated areas are as follows : (1) In the Dove River, a tributary of the Mandamus coming in on the east ; (2) in the Hurunui- Waiau basin ; (3) in the Waikari-Kaiwara basin, or rather trench ; (4) in the Greta- Cheviot basin. The special features of these may be taken in turn. (1.) The Dove River Area. The Dove River basin is important, not from its size, but because it gives an indication of the origin of the landscape features of a considerable area of hill country forming a kind of platform or terrace at the base of the 96 Transactions. higher region to the north-west. The Tertiary beds here consist of the following : — 4. Limestone, passing down into 3. Calcareous breccia with volcanic fragments. 2. Volcanic tuffs and ash-beds. 1. Sands with concretionary layers. The lower parts of these probably contain coal, seeing that an adjacent stream is called Coal Creek. (See also Haast, 1871, p. 30.) The limestone is crystalline in texture, but shows traces of bryozoan forms on its weathered surfaces. The strata are bent up into a sharp syncline whose axis runs north-east, the remnant now existing being less than a mile in length and 300 yards in breadth. The underlying beds are naturally existent over a somewhat wider area, and extend across the Mandamus towards the Hurunui, the direction of one of the reaches of this stream corresponding in alignment and direction to that of the axis of the syncline. The limestone has evidently been squeezed up by folding movements and has occupied the structural basin in which it lies, but the form of the land surface on which the limestone was laid down was not basin-shaped. There are similar basins in the country to the north-west, with parallel orientation, which do not now contain limestone outliers, but their form is so characteristic that their origin is probably similar to that of the Dove. These parallel elements may explain the north-easterly direction of the Hurunui in this part of its course, for after it leaves Maori Gully it apparently follows the line of these basins, with breaks across from one to another. It may be noted also that the hills in this part of the valley rarely exceed 3,000 ft., but immediately to the north-west mountains rise to between 5,000 ft. and 6,000 ft., the marked difference in height being perhaps due to the fact that the lower area was faulted down along a line of settlement parallel to those occurring a short distance away in the Hanmer area and still farther away in the Kaikouras. The indications certainly point to this submontane area having been covered with a veneer of sediments during Tertiary times ; that it was raised with some faulting, and certainly with folding, in late Tertiary or in Quaternary times, the folding producing anticlines and synclines of the beds of limestone with a general north-easterly trend ; and that these limestones were removed from the basins with the exception of that of the Dove. The drainage which now occurs may be called, as Cotton has suggested (1917, p. 253), " anteconsequent," in that it was perhaps conse- quent on the former land surface, but antecedent as far as the present surface is concerned. The determining factors of the original consequent drainage must in this case be highly speculative and almost impossible to determine. (2.) Hurunui-Waiau Basin. The salient features of the Hurunui-Waiau basin have been mentioned before by myself (1915, pp. 347-48). The formation of this mountain- ringed area is attributable primarily to faulting or folding movements, or a combination of both, for there is ample evidence that both are present. The Tertiaries on the north-west side of the basin lie on the basement beds of greywacke with a general dip to the south-east, but with occasional reversals where they abut against the older rocks. This is specially well seen near the road past Mount Mason into the Virginia country, where the limestones in close proximity to the greywackes experience a sharp fold Speight. — Structural and Glacial Features of Hurunui Valley, 97 backwards as if the beds had been dragged down along a fault-line. Farther north towards the Hurunni Gorge, opposite their junction witli the Mandamus, they appear quite normal, but in the Pab.au again their structure is obscure, though that may be attributed to the disturbance in the immediate neigh- bourhood of a volcanic vent. Farther north-east towards Culverden their arrangement is again normal. The floor of the basin is almost completely masked by the gravels of the Hurunui and Pahau Rivers, the only indication of what is underneath being given in the vicinity of Hurunui Mound. Here the Tertiaries rise like an island in the sea of gravels, and they are evidently folded acutely. In the cliffs on the bank of the river near the railway-bridge the structure is anticlinal, but at the Mound itself, about half a mile to the north-east, the beds are also folded, though not on the same line. There is evidence, therefore, of a more complex structure under the plains — that is, they approach a synclinorium. The southern margin of the plain from the road-bridge eastward is determined by a fault-scarp, along the foot of which the river flows. The settlement of the block of country under the plains appears to be more marked on the south-east side (cf. the Waikari and Greta Valleys, also the fault system of the Kaikouras : Cotton, 1914), and the river has therefore occupied it as the lowest level possible on the plains. The outlet, however, is marked by high-level terraces indicating a former higher level of the river. It is almost certain, therefore, that the deformational movements which caused the basin had not terminated wThen the river had established its course through the gap at the south-east corner of the plains. Of such recent movements the surrounding districts furnish ample evidence (cf. . the fault-scarps near Hanmer, at Glen Wye, and also the recent gorge of the Middle Waipara). The course of the river from the junction of the Mandamus has followed the line of steepest descent to the fault-line, and is therefore approximately at right angles thereto. This explains the necessity of the sudden sharp turn when the line of the fault is reached. Although the high-level terraces at the outlet may be attributed to recent movements in the basin itself, they may be correlated with the uplift which all this region has recently experienced, and therefore are the result of the river accommodating itself to a new and lower base -level. The river-course across the plains is marked by terraces of no great height. It here follows a direction consequent on a surface of its own making, for which the term auto-consequent could be used. Thus the courses of the Rakaia, Rangitata, and other large rivers of Canterbury across the plains are auto- consequent. (3.) The Waikari-Kaiwara Basin. After leaving the Culverden Plain the river flows through a gorge cut in greywacke for about six miles till it enters on the Waikari-Kaiwara basin. This extends down the river to the immediate vicinity of the Ethelton railway-station, when the river passes through another gorge cut in greywacke. The basin is therefore completely enclosed by pre- Tertiary rocks. Although the area has a basin-shaped form, its origin is somewhat different from the Waiau-Hurunui intermontane area, and owes its formation entirely to the faulting-down of a strip of Tertiary beds and the subsequent enlargement of the tributary valleys through the rapid erosion of relatively weak beds. These consist chiefly of sands with harder concretionary bands, sandy clays, and marls, with occasional irregular layers of shells, mostly in a fragmentary condition : they are, in fact, the equivalents of the Motunau or Greta beds. Mount Brown beds are existent 4 — Trans. 98 Transactions. as well, but I have found no appearance of limestone, which is so well de- veloped in the Waikari district to the south-west. Limestone does occur in the upper part of the Scargill Valley, in the form of faulted strips, but I have not traced it farther towards the Hurunui. The beds have a general north-east strike, and a dip to the south-east of from 15° to 20°. Where the beds cut across the Hurunui. which they do at an angle of about 45°, they are disturbed from their proper dip and are pulled up along the line of a fault on the downthrow side till they are nearly vertical ; but this disturbance does not extend far from the fault-line, and may be attributed entirely to the movements caused by it. The result is that the beds form a strip running along the north-west side of the Waikari-Kaiwara de- pression, with slope accordant to that of the underlying surface, and if they were removed a characteristic " stripped surface," as described by Thomson,* would be disclosed. I do not know what special name has been applied to valleys of this form, except that I think the term " basin range valley " has been applied to somewhat similar valleys in the western United States ; but the Waikari Valley is of a somewhat different type, and also the name just cited is an unfortunate conjunction of terms. The name " rift valley " does not apply, because such are determined by faulting running along two sides, whereas these under consideration are attributable to tilting which has accompanied faulting along one line only. I suggest the name tilted strip as being a suitable name in case none has been already applied. The most remarkable feature of the course of the Hurunui is its con- tinuance across this depression without any apparent effect on its course. Although the earth-movements accompanying the faulting must have been of fairly recent date, the river has maintained its original course. It is interesting to compare this case with that of the Clarence Valley, farther north, where a similar valley caused by faulting on a much larger scale has dominated the course of the river. In the case of the Hurunui the movement must have been slow, and some cause must have been present which enabled the river to reach a lower base-level almost as fast as the downward movement occurred in the beds in this portion of its course. This cause will be evident from a consideration of the features of the next compartment into which the river-valley has been divided. (4.) The Greta-Cheviot Basin. The greywacke gorge of the river continues for about three miles below the Ethelton Station, when the valley opens out and the river has a wide shingly bed with flanking terraces cut in the marls of the Motunau or Greta series. Soon after its emergence from the gorge it receives the small Greta Creek, which occupies a valley similar in form and origin to that of the Waikari and Kaiwara. The beds let down by the fault which determines this valley develop northward into those of the true Cheviot basin, which is some five miles across, and extends past the Cheviot township across the Waiau as far as the Conway River. The structure of this basin is dominantly synclinal. The beds exposed on the floor of the basin are clays, sandy clays, sands, &c, of Mio-Pliocene age, passing down conform- ably into calcareous oreensands (= Weka Pass stone) and hard limestone (= Amuri limestone). The limestone is exposed in places along the western edge of the greywacke ridge which separates the basin from the sea, and through which the Jed has cut its gorge. On the seaward side of this grey- * J. A. Thomson, Coal Prospects of the Waimate District, South Canterbury, N.Z. Geol. Survey. 8th Aim. Rep., p. 1(50, 1914. Speight. — Structural and Glacial Features of Hurunui Valley. 99 wacke barrier the limestone also occurs, with reversed dip, and under the limestones are exposed sands and greensands with saurian bones, and thin beds of impure coal. On following the beds across the strike a synclinal arrange- ment is found, and the limestone forming the south-eastern limb appears as a reef at Port Robinson, striking out to sea just as the limestone reefs do at Amuri Bluff. This syncline is well seen in the cliffs at Gore Bay, and it no doubt extends south-west as far as the Hurunui, and appears where the rocks dip up-stream just above the lowest bridge across the river. The upturned beds of the south-easterly wing of this syncline rest at Port Robin- son on greywackes, and at the Hurunui Bridge on the same rocks. In the last-mentioned locality there is evidence that the Tertiaries are bent over this core of grey wacke in mild anticlinal arrangement. The river has cut a gorge through the greywacke, which has been used as a solid basis for the abutments of the bridge. Up-stream from this, the traces of the anticlines and synclines which occur between Port Robinson and Cheviot can be seen occasionally where the Motunau beds are exposed in the river-terraces, but no limestone is visible ; the general arrangement is, however, synclinal. An important point as regards the history of the river is the compara- tively recent elevation of the coast-line. This has amounted to as much as 600 ft., judging from the shore-platforms extending to that height at Port Robinson, between the mouths of the Hurunui and the Blyth Rivers (three miles to the south), and just south of the Blyth River on the summit of the Napenape Cliffs. This elevation has been noted previously by Haast, Hutton, and McKay. In the last-named locality there are sea- planed limestone surfaces 600 ft. above sea-level covered in places with marine gravels. In the country just south of the Hurunui this plain of marine denudation extends back from the present coast-line for some five miles to the base of the greywacke hills, and exhibits a peculiarity in that the wave-cut surface is higher near the coast than farther inland. This suggests that a slight warping has taken place since the plain was cut ; but the peculiarity may perhaps be explained by the more ready erosion of the softer beds farther inland than the harder limestone exposed near the coast where it forms the floor of the high platforms. The first explanation is, however, the more reasonable, and if it is correct the axis of warping would approximate to that of the line of the greywacke bar near the river- mouth. Apart from the effect on the river in this vicinity, probably apparent in the gorge of the river incised in a somewhat wide flood-plain, an elevation of the land totalling some 600 ft. would exert considerable influence on a river which had reached approximate base-level, as it is reasonably certain that the Hurunui had, before the coastal elevation took place. The power of vertical corrasion would be greatly increased over a considerable part of the course of the river. At the present time a considerable portion of the Culverden Plains are under 600 ft. above the sea, and unless some compensa- tions in level have taken place inside the coastal belt the level of the river- bed should have been greatly affected as far as the junction with the Man- damus at least, where the solid bars of rock would delay adjustment for a long period after it had taken place in the relatively weaker beds farther down-stream. There is, however, evidence of a lowering of the inland portion of the river-basin relative to the coastal portion as a result of the faulting which took place on the Greta line, on the Waikari-Kaiwara line, and again in the deformational movements of the Hurunui-Waiau basin. The effect of this would be to make this portion of the stream an aggrading one if the lowering were in excess of the coastal elevation. This has certainly been the case, for the aggregate throw of the faults must total 4* 100 Transactions. considerably over this. The effect of this has no doubt been to make the river an aggrading stream in that part of its course which lies in the Cul- verden Plain, and to neutralize the effect of the elevation perhaps as far down as Ethel ton, but to rejuvenate the part between the Greta and the sea. Even this part is near a temporary base-level, judging by the great amount of shingle in its bed and the very low terraces of some parts of its course. This rejuvenation enabled the river to maintain its course in its lower portion across the grain of the country, to cut deep gorges through greywacke rocks, and to do this in spite of movements which would tend to turn it from its original course. As the present valley of the river is situated, there are several easier routes than that which it actually follows, such as that past Hawarden down the Waikari Valley, or past Hawarden into the valley of the Waipara and thus into the sea near Amberley. But it appears that under certain conditions, when the course of a river is once definitely established it will maintain that position in spite of influences which should divert it from its original path. Development of the Course of the Hurunui Eiver. The geological features of this region which have primarily determined the course of the river are briefly stated as follows : On a greywacke sur- face, incompletely base-levelled, a series of beds was deposited chiefly in middle and late Tertiary times. These consist of sands sometimes with coal, greensands, limestones, marls, sandy shell-beds, and sandy marls passing up into conglomerates, the higher members being of Pliocene age. The general character of the strata indicates deposition on a sinking sea- bottom in the early part of the period, followed by deposition on a rising bottom at the end, the whole sequence being laid down without a physical break. It is probable that there was some differential elevation towards the close of the time, so that some of the earlier beds were eroded in places while continuous deposition was going on elsewhere. The sea in which deposition took place gradually extended over a wider area with the sinking of the land, since the higher members overlap the lower and cover a more extensive area. Thus it is that limestone is very thin or entirely absent in certain localities — for example, the Greta and Waikari Valleys — the land occupied by those localities being the last to be invaded by the sea during submergence, and having an entirely different form from that which it now has. No doubt a slightly elevated area occupied the site of those valleys in early Tertiary times. The covering beds extended far to the eastward, but have been cut back bv marine erosion, which is at present making marked inroads on the sea-cliffs composed of loose sands and marls ; while to the westward the Tertiaries extended beyond the Mandamus Eiver, probably to the vicinity of Maori Gully, but fragments of the greywackes rose like islands in the cover of more recent beds, though not in the position of the high lands existing at present. On this surface of covering beds as it emerged from the sea a consequent drainage was established, consisting of subparallel streams running seaward in an easterly direction. Although it cannot be stated with certainty, it is probable that the first elevation of the land took place with comparatively little deformation, and the river-courses were well established before the dislocations became pronounced. After the rivers had been completely established, folding and faulting took place on lines cutting the direction of the main streams at an angle of approximately 45°, and these lines have determined the courses of the principal tributaries, most of which enter the main valley along fold and fault lines. The recency of the movements is Speight. — Structural and Glacial Features of Hurunui Valley. 101 emphasized by the marked dependence of the landscape forms on the features resulting immediately from these movements. In some cases time has not been sufficient for the weak covering beds to be removed from the higher elevations, though in general these are more, perfectly preserved in the folded and faulted intermonts. The movements producing these must have been slow, although they have been comparatively recent, since the main stream has preserved its original direction with but slight modifications, in spite of- the opportunities presented for departing from it as a result of these movements, while farther north in the Kaikoura region the movements were on such a scale that the stream-systems are almost entirely dependent on them for their direction. The Hurunui region thus illustrates the con- dition that a powerful stream may at times maintain its original direction in spite of strong forces tending to deflect it. Dr. Cotton has drawn my attention to a paragraph in a paper by Professor W. M. Davis, entitled " An Excursion in Bosnia, Hercegovina. and Dalmatia," * which seems appropriate in this connection. It reads as follows : It is evident that this hypothesis [warping] accounts simply enough for the occurrence of irregularly alternating basins and uplands ; and that the basins thus pro- duced might lie connected by gorges eroded through the uplands by the master rivers : the gorges marking either the paths of antecedent streams that had maintained their course in spite of the warping, or paths selected by the drainage consequent on some early stage of warping and antecedent to the rest." This idea of anteconsequent streams has been elaborated by Cotton (1917. p. 253), and it seems entirely applicable to the case of the Hurunui. except that faulting has ensued as a result of the strains set up in the warping movements. Glacial Features of the Hurunui Valley. (See map, fig. 2.) Although there are no present-day glaciers in the valley of the Hurunui, the mountains not being sufficiently high in that part of the alpine region to intercept sufficient snow to feed them, the upper part of its basin was subjected to the severe glaciation which affected a large part of the South Island of New Zealand in Pleistocene times and perhaps later. Haast has indicated (1879, plate 11) that the Hurunui Glacier at its greatest exten- sion came down below the junction of the Waitohi River with the main stream — that is, well on to the Culverden Plains ; but on what evidence he bases this meat extension is not clear, and in my opinion there is no reason to demand it. The absence of morainic and other glacial deposits, as well as the form of the river-valleys in the middle course of the Hurunui, render his supposition very improbable. Especially is the latter evidence strong in the case of Maori Gully, the striking gorge which the river has cut in the edge of the high-mountain country before it runs through the foothills of the Alps. This is so deep and narrow that it is almost impossible that ice could have come through it and left it in its present condition. It seems to me extremely probable that the ice did not extend below the junction of the two main branches of the river, if. indeed, it came so far, since there is no proof of its former presence even at this point except the somewhat indefinite evidence based on the form of the river-valley, which may be attributable to ice action or may be the result of ordinary stream erosion. In the absence of other proof this solitary line of evidence must be viewed with considerable reserve. Bull. Grog. Soc. Philadelphia, vol. :L No. 2, pp. 21-60, 1001. 102 T ransa ctions . Above the junction of the two branches the evidence is undoubted, especially from the vicinity of the Lakes Station and Lake Sumner towards the head of the river. Old moraines, smoothed and rounded surfaces, and the form of the cross-section' of the valleys furnish indubitable evidence of the former presence of ice. In the upper part of the course of the North Branch the even alignment of the valley-walls, their steep lower slopes and gentler upper ones, the truncated and semitruncated spurs, and the roches moutonnees on the valley-floor are as characteristic of the results of glaciation as anything in the valleys of the Southern Alps farther south. On the north side of the river the mountain-tops have a very flat plateau- like form, and this feature continues as far as the valley of the Waiau, if n L/A/E.S OF C///£:/r G LAC ML. STtfgAMS Fig. 2^— Upper Hurunui Valley. not|farther,^so that the streams run in deep trenches incised in the table- land. To the south of the river the mountain-tops are more like those characteristic of middle and southern Canterbury, with rugged summits and wide expanses of moving debris dislodged from solid rocks by the action of frost. To the east of the plateau region the mountains take on this form even to the north of the river. Specially interesting features of the river-basin have resulted from the action of these ancient glaciers on a mature valley-system which had become established in pre-glacial times. These features are so strongly remi - niscent of those of the valleys farther south, especially of the Waimakariri, that thev must be attributable to a common cause. The only difference in the two cases is that the features of the Hurunui are not so strongly marked, which is no doubt due to the more moderate intensity of the glaciation in the northern river. Thus there are distinct traces of the original directions of the streams, which are wanting farther south, but which may give some clue to the origin of the characteristic features of the valleys. Parallkl Valley System of Upper Part of Basin. The most striking landscape form of the upper basin of the Hurunui is the series of subparallel valleys flanking the North Branch on its southern side. These are quite analogous to those of the Waimakariri, also on its southern side, and to those in the vicinity of Lake Coleridge in the valley Speight. — Structural and Glacial Features of Hurunui Valley. 103 of the Rakaia. The arrangement is as follows, taking the valleys in their turn, commencing from the north : — (1.) The main valley of the North Branch leading into Lake Sumner. This has a general east-and-west trend, with wall-like sides in good alignment, I nit broken by tributary valleys, especially on its northern side. Lake Sumner occupies a continuation of this valley, but about half-way along the lake the trend assumes a north-west and south-east direction more in agreement with that of the others. This corresponds in direction and salient features with the main valley of the Wainiakariri. but the landscape characters are on a smaller scale. (2.) The set of subparattel valleys lent/inn from the vicinity of the head of Lake Sumner, near Lake Katrine, and running south-east. At the head of the system there is only one main valley, but it breaks up within a short distance into distributaries consisting of- (i) A valley immediately to the south of Lake Sumner and divided therefrom by a ridge of which the peaks known as The Brothers (4,563 ft. and 4.507 ft.) are the highest points ; (ii) a valley in which lies Lake Sheppard, divided from (i) by a discontinuous ridge ending in The Sisters (3,281 ft.) ; (iii) a valley in which lies Lake Taylor, divided from the former by Conical Hill (2,783 ft.) and from the valley of the South Branch by the Oronoko Range. These valleys are quite analogous to those in the Wainiakariri basin, which may be called (i) the Lake Black- water Valley, (ii) the Lake Sarah - Sloven's Creek Valley, and (iii) the Lake Grassmere - Lake Pearson - Winding Creek Valley. They also resemble the still more remarkable and perfect system to the east of the Rakaia basin in the vicinity of Lake Coleridge. The ridges which divide these valleys are analogous in their physical characters. They are very steep-sided, with somewhat narrowed cross- section, so that when viewed end-on they appear conical ; hence the frequent occurrence of such names as " Sugarloaf " and " Conical Hill ** in North Canterbury. But when viewed from the side they form long ridges cut into well-defined saddles (c/. Mitre Peak). When this saddle is low and little elevated above the floor of the valley in the vicinity the ridges become isolated hills, which are often in pairs or linear series, and give rise to such names as " The Brothers " or " The Sisters.'" The valleys indicated above junction with the main valley of the North Branch after it leaves Lake Sumner and takes the first decided bend of the river to the south-east. It soon afterwards receives the South Branch. In its upper part this valley has an east-west direction, but it soon takes on the characteristic north-west and south-east orientation, and finally turns and joins the other branch nearly at right angles. The dividing wall be- tween it and the Lake Taylor Valley to the north, called the Oronoko Range, has been partially broken down in several places. The most important of these lies just opposite the head of Lake Sumner, where a low pass leads from the northern to the southern valley of the Hurunui. On the southern side of the pass is Lake Mason, tucked away in a tributary valley of the South Branch. The country in this neighbourhood has been highly glaciated, rochet moutonnees and smoothed surfaces forming characteristic features of the landscape. Opposite the Lakes Station there is another saddle — some- what high, it is true and the ridge has also been lowered in a line with the Lake Taylor Valley leading directly to the North Branch south of Dog- Hill, indicating an overflow in that direction. The partial dismemberment of this ridge affords a clue to the conditions which obtained before dissection and isolation overtook the ridges to the north-east. By noting its features it is possible to restore with reasonable 104 Transactions. certainty the general direction of the streams that flowed through this tract of country anterior to the glaciation. In addition to the two main branches of the river a large stream rising near the head of Lake Sumner followed the course of the Lake Taylor Valley, parallel with the South Branch ; this entered the North Branch about half-way between Lake Sumner and the junction of the two main branches. A small tributary entered this valley on the north side, rising near the head of Lake Taylor and following the course of Lake Sheppard. Another small stream rose near Lake Katrine and joined the North Branch below the outlet of Lake Sumner. In pre-glacial times the ridges dividing these valleys would be more or less entire, though they might have saddles at their heads. It is impossible to reconstruct such features exactly, but the description just given affords a fairly accurate view of the stream conditions which obtained in this tract of country before it was modified by glaciation. Whatever was the prime cause which promoted glacier extension, it is reasonable to assume that it was gradual in its incidence. Snow would slowlv accumulate, glaciers would be formed at higher altitudes and slowly extend down the valleys. Thus the heads of the small valleys would pro- bably be filled with corrie glaciers, while the glaciers of the first order would be extending down the main valleys. These would help to lower the divides in the way suggested by Matthes.* As the ice-flow increased in volume the main streams would be filled, and in time overflows would take place over the lowest part of the divides, which would be lowered at the same time by active ice abrasion. It is significant that the greatest amount of lower- ing has taken place near the head of Lake Sumner. This would be due to the marked overflow of ice from the main Hurunui Valley, no doubt due to the narrowing of the cross-section of the valley at Lake Sumner, which caused the ice to overcrowd into the headwaters of the neighbouring streams, as it has done in several of the valleys of the Canterbury rivers. The full force of this would be felt at the head of the Lake Taylor Valley, and thus its divide has been completely reduced. The headwaters of the intermediate tributary valleys were also invaded and the saddles at their heads reduced. Thus a clear passage for the ice was opened down these valleys past the site of the Lakes Station in the direction of the south-easterly reach of the North Branch below Lake Sumner, while the main stream of ice followed down the valley now occupied by this lake. In addition to the overflow toward Lake Taylor, a powerful stream passed over into the tributary which runs into the South Branch from the north. The saddle at the head of this stream was thus reduced, but not so much as its neighbour, which was more in the line where the ice-stream would impinge on the valley-wall. If, however, glacier action had continued this saddle would have been reduced and the mountain ridge to the north of the South Branch would have been completely isolated. It is possible that ice also overflowed into the valley of this stream near the Lakes Station, and as at the height of the glaciation the country in its vicinity would have the form of an intermontane basin, and would be an efficient gathering- ground, overflows from it took place along several lines from the front of the ice-sheet in the direction of the valley of the North Branch. These would produce the breaks in the valley-wall between the South Branch and the country to the north which occur immediately up-stream from the junction of the two branches. * F. E. MATTHES, Glaciation of the Biu Horn Mountains. U.S. Geol. Sun: 21st Ann. Rep., 189U--1900. Speight. — Structural and Glacial Features of Kurunui Valley. 105 The dismemberment of the ridges would no doubt be promoted bv the sapping-back of the valley-walls and their complete reduction in places where the ice-stream impinged more powerfully. If we compare the results of the glaciation in other valleys we see that in their cases the dismember- ment has been more complete, the dissection of the dividing ridges carried to a further stage, and the straightening of their sides more thoroughly carried out. because they experienced more complete glaciation. If we were furnished in these cases with more clear indication of the intermediate condition of the direction of drainage it would be possible to reconstruct the original stream-system. There is one point, however, which has not been considered fully — viz., the agreement in the direction of the tributary valleys with those of the Waimakariri and Rakaia. Is this agreement in orientation the result of accident, or is it based on some structural condition which has influenced the country in the basin of the Hurunui as well as the country farther south '. I have shown (1916, pp. 142-43) that there exists in the mountain region of Canterbury a well-marked series of fractures or lines of folding which lie in a north-west and south-east direction. Cotton (1917, p. 273) draws special attention to the importance of the north-west system of earth- fractures in Otago as compared with the other parts of this Island, but they certainly occur in Canterbury in conjunction with the Kaikoura system, and it is possible that in the upper Hurunui, as in the Waimakariri, they are co-existent. Since writing the article referred to above I have noted additional lines with the north-west orientation, especially in the upper valley of the Waipara and in South Canterbury in the country between Fairlie and Cave. In both these cases there are undoubted, well-marked lines of fault. It is possible, therefore, that the general direction of the valleys at the head of the Hurunui were determined initially by lines of structural weakness. It is remarkable also that some of the valleys on the northern side of the river have a characteristic east-north-east orientation, and these are parallel to other valleys farther north, such as the Hope, in the basin of the Waiau. On the line of one of these upper valleys is the hot spring which forms a notewerthy physical feature of the Upper Hurunui, and I am informed that other springs occur in the valley which stretches north-east from this locality. This certainly points to the presence of an earth -fracture with east-north-east orientation. Another feature of this district should be noted — viz., the north-and- south trend of the upper valleys of the Waiau and Clarence, a direction which is parallel to the twin valleys of the Mandamus, and to that of the Glenrae, lying to the west of these. The arrangement may be only a coincidence, but it is certainly a striking one. Bibliography. Cotton, C. A., 1914. The Physiography of the Middle Clarence Valley, New Zealand.. Geo;/. Journ., vol. 42, pp. 225-46. 1917. Block Mountains in New Zealand, Am. Journ. Sci., vol. 44, pp. 249-93. Haast, J. vox, 1871. Rep. Geol. Explor. dur. 1870-71, pp. 30, 48, sections. ■ 1879. Geology of Canterbury and Westland, pp. 69-78, 216-17. Hutton, F. W.; 1877. Rep. Geol. Explor. dur. 1873-74, pp. 34-35, 55-56. — 1889. The Eruptive Rocks of New Zealand, Trans. Urn/. Soc. N.S.W., vol. 23, pp. 125. 15li. Speight, R., 1915. The Intermontane Basins of Canterbury, Trans. N.Z. Inst., vol. 47. pp. 347-48. 101 (i. The Orientation of the River-valleys of Canterbury, Trans. N.Z. Inst., vol. 48, pp. 137-44. 106 Transaction*. Art. VII. — The Volcanic Rocks of Oamaru, ivith Special Reference to tlicir Position* in the Stratigraphical Series. By G. H. Uttley, M.A., M.Sc, F.G.S., Principal, Scots College, Wellington. [Read before the Wellington Philosophical Society, 16th July, 1016 ; received t>y Editors, 31st Deceinber, 1917; issued separately, 24th May, IH18.] Contents. I. Introduction. II. Succession of the Rocks of the Oamaru Series. III. Previous Opinions in regard to the Horizon of the Volcanic Rocks. IV. Effects of these Opinions on the Classification of the Oamaru Series. V. Descriptions of the Sections. (1.) Oamaru Lighthouse. (2.) Oamaru Rifle Butts. (3.) Hutchinson Quarry and Neighbourhood. VI. The Pillowdavas. VII. Chemical and Petrographical Notes. VIII. Conclusion. I. Introduction. Interpretations of the geology of the Oamaru coastal district where the typical Oamaru series is developed have varied greatly in the past, and, although there is now pretty general agreement as to the broad features of the rock-sequence, it is essential that more detailed stratigraphical work should be attempted if the best results are to be obtained from the deter- minations of the Tertiary fossil Mollusca and Brachiopoda, which are being carried out by Mr. H. Suter and Dr. J. Allan Thomson. Many of these fossils have been collected from the Oamaru district, the exact locality and rock from which they have been gathered are known, and, if the strati- graphical sequence can be determined in greater detail than has been done in the past, correlation of Tertiary rocks in other parts of the Dominion with those developed in the typical locality will possess a sounder basis than it does at present. Misinterpretations of the rock-sequence at Oamaru have undoubtedly been caused by faulty identification of the horizons of the volcanic rocks, and it will assist stratigraphical work if these can be determined more accurately. The position of the lowest volcanic rocks, the Waiarekan, is not in ques- tion ; it is generally agreed that they lie immediately below the Ototara limestone, and my work in the North Otago district has convinced me that they are invariably associated with deposits of diatomaceous earth in the Oamaru and Papakaio areas. Difference of opinion has, however, been sharply marked when dealing with the volcanic rocks near the Oamaru coast. These have been correlated with the tuffs in the Waiareka area ; important unconformities have been introduced into the sequence, on the ground that the volcanic rocks are clear evidence of the existence of a former land surface. An attempt will be made in the present paper to define more clearly the place of the volcanic episodes in the late geological history of the Oamaru district. In 1916 I gave a detailed sequence of the rocks east of the Waiareka Valley, and some of the evidence on which the succession was based was presented in that paper. It is now proposed to bring additional evidence by describing several sections in the neighbourhood Uttley. — Volcanic Hocks of Oamaru. 107 of the town of Oamaru. The pillow-lavas that occur in some localities will be described, and a preliminary reference will be made to the micro- scopic characters of some of the rocks, a detailed description of which must be reserved for a future paper. I am much indebted to Dr. Thomson and Mr. H. Suter for naming many of the fossils. Their determinations are indicated by an asterisk placed in front of the name of the fossil. The other determinations have been made by myself by comparison with forms determined by these palaeontologists. II. The Succession of the Rocks of the Oamaru Series. It will be advisable at the outset to state briefly the detailed succession of the Oamaru series as developed in the typical locality. The classification of the upper rocks is based mainly on evidence to be brought forward in this paper. To the west of Oamaru, in the basin of the Kakanui River, the lowest Tertiary rocks are the grits, clays, and sandstones, sometimes associated with lignite deposits, the whole forming the Ngaparan stage. These are followed by a considerable thickness of greensands, and these in turn are succeeded by a great thickness of breccias and tuffs, occurring in the Waia- reka Valley. Towards the top these become fine-grained and tachylytic, and are interbedded with deposits of diatomaceous earth, which, in addition to the vegetable micro-organisms, contains an equal abundance of sponge- remains and Radiolaria. Dykes and sills have intruded the tuffs and diatom- aceous earth, and the siliceous rock has in many places been completely metamorphosed into a flinty substance. These constitute the Waiarekan stage. The Ototara limestone is the next succeeding rock. In its lower portions it is interstratified with thin beds of marl, and occasional thin layers of rolled volcanic pebbles. In its middle portion it is in some localities intercalated with tufaceous bands, but these are probably detrital only. In other localities the deposition of the limestone continued uninterruptedly ; and it is free from volcanic material. Towards the end of the limestone period volcanic activity was renewed in localities near the present coast- line with the eruption of the breccia at Kakanui and the volcanic rocks in the neighbourhood of Oamaru, the upper pillow-lava of the latter locality being younger than the breccia. After volcanic action had ceased limestone continued to be deposited, but in many places it contains large well-rounded masses of volcanic rocks, and minerals similar to those occurring in the breccia below. It is more than probable that the Kakanui breccia formed small islands or submarine banks, for it is followed by limestone bands and tuffs, the former containing rolled fragments of the breccia. In Oamaru Creek these interstratified tuffs and calcareous bands are invaded by a thick mass of dolerite which has overflowed to the north and formed the upper pillow-lava near Grant's Creek. This in its turn is followed by the limestone containing the large volcanic boulders. The latter disappear towards the top of the limestone, which closes the Ototaran stage. The greensands of the Hutchinsonian stage followed the limestone, and the sequence closed with the mudstones of the Awamoan stage. III. Previous Opinion in regard to the Horizon of the Volcanic Rocks. Hector (1865) considered that the volcanic rocks near Hutchinson Quarry, in the town of Oamaru, were submarine, but he based his conclusion on the 108 Transactions. erroneous assumption that the hard limestone bands in that locality had been metamorphosed during deposition by a lava-flow. Hutton (1875, p. 54) said, " No eruptive rocks are found associated with the older or Ototara group of strata .... but at Oamaru Heads we have clear evidence that during the deposition of the Upper or Trelissic group of beds volcanic action was going on." In 1876 McKay placed the Waiareka tuft's below the Ototara stone, and asserted that a younger series of volcanic rocks occurred at Oamaru. In 1886 Hutton verified McKay's observations as to the position of the Waiareka tuffs, but repudiated his own former statement that volcanic rocks were associated with the upper beds of the series. He recognized but one horizon of volcanic rocks, the Waiarekan, and considered that the volcanic matter in the upper part of the limestone was detrital only. In 1905 Park asserted that volcanic activity commenced at the end of the Waihao greensand period and culminated during the deposition of the Hutchinson Quarry beds. Summarily, according to McKay there were two distinct periods of eruption, the pre-Ototaran and the pre-Hutchinsonian ; according to Hutton but one, the pre-Ototaran ; while according to Park activity continued during the Waiarekan, Ototaran, and Hutchinsonian periods. IV. Effects of these Opinions on the Classification of the Oamaru Series. The fact that the volcanic rocks are always followed by limestone has undoubtedly caused confusion in classification, and in the absence of distinctive fossils in the limestone the igneous rocks near the coast have been assumed to be Waiarekan. McKay, although recognizing the Tertiary volcanics at Oamaru as distinct from his Cretaceo-Tertiary Waiarekan tuffs, erroneously supposed the breccias at Kakanui to be Waiarekan (1877, p. 56), whereas they are middle Ototaran. Hutton in ascribing the volcanic rocks at Oamaru to the Waiarekan was necessarily compelled to introduce an unconformity above them to account for the non-existence of the Ototara stone. Park's contention that volcanic activity culminated during the Hutchinson Quarry period may be true or not true ; it depends entirely on the connotation of the term " Hutchinson Quarry beds." McKay seems to have been the first geologist to use the term in classification (1882, p. 58). Later in the same report (p. 76) he seems to restrict the term to the green- sands alone, correlating the calcareous beds with the Otekaika limestone, and the volcanic rocks below with the Kekenodon beds. In other words, in the typical locality he excludes the limestone bands. This is in sub- stantial agreement with Thomson's use of the term 'Hutchinsonian" (1916, p. 34). Hutton was probably correct in considering much of the volcanic matter detrital only, as will be demonstrated in the sequel. Further, McKay con- sidered the volcanic rocks of Oamaru Creek as evidence of a land surface, and he supposed the overlying rocks to be markedly unconformable to them (1877, p. 58). My own opinion, based on the evidence furnished below and on further observations in other parts of the Oamaru district, is that deposition was continuous from the base of the Ototaran to the top of the Awamoan, but interrupted locally by submarine eruptions resulting in the formation of volcanic banks or islands, which, however, suffered rapid denudation, and this minor phase is recorded in the slight unconformities now to be seen in the tnfaceous beds. Uttley. — Volcanic Rocks of Oamaru-. 109 V. Descriptions of the Sections. (1.) Oamaru Lighthouse. In the sea-cliff below the lighthouse near the Oamaru Breakwater a good section is exposed (see fig. 1). The. tufaceous beds (a) are interstratified with limestone bands, which often contain large subangular pieces of vesicular basalt. The bands themselves vary up to 1 ft. in thickness, the lowest being 170 ft. below the base of the lower pillow-lava. There is a marked discordance in the dip of the tufaceous rocks below (a). These are not shown in the figure. They dip 40° N. by E., while the dip of (a) is only 20° N. by E. It is probably at this point that McKay introduces his unconformity between his Cretaceo-Tertiary and Upper Eocene beds (1877, p. 58). From the calcareous bands in the tuffs I collected the following forms : *Emarginula wannonensis Harris, Siphonalia sp., Dentalium solidum Hutt., *Pecten hutchinsoni Hutt., Sip/ionium planatum Suter, Liothyrella oamarutica (Boehm), L. boehmi Thomson, Terebratulina suessi (Hutt.), Aetheia gualteri (Morris), and Hemithyris sp. The overlying pillow-lava is at a minimum estimate 100 ft. thick. The interspaces are filled with fossiliferous limestone, much hardened in places by a secondary deposit of calcite, and the fossils are difficult to extract A detailed description of this peculiar rock and others similar to it will be given later. The following fossils were obtained from the interstitial lime- stone : *Trochus sp., *Turritella sp., *Polinices huttoni von Ihering, *Lima bullata Born, *Lima lima (L.), Ostrea sp., and Hemithyris sp. d, e f q jrIG. i. — Section near lighthouse, Oamaru. (a) Tuffs with limestone bands ; (b) lower pillow-lava ; (c) fine tuffs (current-bedded) ; (rl) tuff- bed (very calcareous) ; (e) limestone band with rounded and subangular pieces of volcanic rock ; (/) blue tufaceous clay ; (g) limestone ; (h) tufaceous limestone ; (j) raised beach ; (k) broken pillow-lava. The tuff-beds (c) are very fine and current-bedded, but unfossiliferous. The overlying tuffs (d) are very calcareous and coarser in texture. I col- lected the following forms : Epitonium lyratum (Zitt.), Lima Jeffrey siana Tate, Ostrea sp., Venericardia purpurata (Desh.), and Diplodonta zelandica Gray. The limestone band (e) is crowded with subangular pieces of volcanic rocks, while small pieces of augite were also identified. Bed (g) is a much purer limestone than bed (h), which is very tufaceous. In the limestone (g) the following forms occurred : Epitonium lyratum (Zitt.), *Pecten hutchinsoni Hutt., *P. delicatulus Hutt., Terebratulina suessi (Hutt.), *Liothyrella boehmi Thomson (?), and *L. oamarutica Boehm. The overlying tufaceous limestone (h) is also fossiliferous, and the following species were identified : *Limopsis aurita Brocchi, Pecten deli- catulus Hutt., *Lima jeffreysiana Tate, Ostrea sp., ^Venericardia purpurata (Desh.), V. zelandica (Desh.), Protocardia pulchella (Gray), .and Terebratulina suessi (Hutt.). 110 Transactions. This bed passes insensibly into a completely tufaceous bed with occasional pillows scattered through it. The tufaceous matter, however, rapidly diminishes, and the rock becomes a pillow-lava, which will be discussed in the sequel. (2.) Oamaru Rifle Butts. Near the Oamaru Rifle Butts, on the south-west side of Oamaru Cape, a clear section is exposed on the beach. It is interesting, as the pillow-lavas are absent and a bed of limestone nearly 50 ft. thick is followed almost immediately by the Hutchinsonian greensands. A fault occurs immediately north of this section, and just beyond the fault there is a marked strati- graphical break in the tuff - beds, exactly similar to the unconformity described in the tuffs near the breakwater. The section extends from a point immediately north of the target sheds to the fault which cuts the tuft's just past the first headland. S50°W Fig. 2. — Section northwards from Rifle Butts, distance about 160 yards, (a) and (ax) tuffs ; (6) calcareous fossiliferous tuffs, 1 ft. ; (c) limestone agglomerate, 2 J ft. ; (d) (7 ft.) and (dt) (40 ft.) limestone; (e) fine blue tuffs, 8ft.; (/) greenish calcareous tuffs, 11 ft. ; (lant-associations are described by Cockayne and Foweraker,f and such a description is essential as a basis for any attempt at detailing the modes of life of the insects. The plant-life of the area is to a certain extent unaltered by the advent of man. The forest, the shrub-land, and the river-bed and rock plants are probably almost entirely primitive. Even the tussock-land has been altered but little, and the alteration that has occurred seems more in the direction of varying the proportions of the primitive plants than in their replacement by introduced species. * C. Chilton, Notes from Canterbury College, .Mountain Biological Station, No. 1" Tru»s. X.Z. Ins!., vol. 47, p. 331. 1915. t R. Speight, ibid., vol. 48, p. 145. 1916. I L. Cockayne and C. E. Foweraker, ibid., vol. 48, \>. 166, L916. 136 Transactions. Hypochaeris radicata, however, is found all over the open country, and is freely visited by the small bee DasycoUetes hirticeps. Trifolium minus, . too, which occurs in the gullies, is probably visited by some insect, as it sets seed freely, and the seeds have been germinated from sheep-dung. These are the only cases noted where change of vegetation may have influenced insect-habits. In the animal world, however, or at least in the vertebrate world, the most profound changes have been made. Over practically the whole of the area the sheep reigns supreme, and the effect of its grazing upon certain flowers has doubtless been reflected on the insect population. With the sheep has been introduced Oestrus ovis, the sheep's nasal bot-fly, which lays its eggs in the sheep's nostrils, so that on hot days the persecuted beasts may be seen stamping their feet, tossing their heads, or standing huddled together with noses to the ground. Sheep's dung, too, must be fed upon by numerous maggots and beetles, and the animals that die have a marked effect upon the numbers of blow-flies that infest this and all similar locali- ties. Except the sheep, the only mammal that could affect the vegetation is the hare, and of this only occasional specimens are seen. Bird-life is not at all plentiful, and has probably changed considerably as a result of human occupation. Of water-birds, the paradise duck (Casarca variegata) is the most common, flocks of twenty or thirty being frequently seen on Lake Sarah and in the swamps. Grey ducks (Arias superciliosa) and a very tew black swans also occur on the lake. An odd pukeko (Porphyrio mdano- notus) may be seen in the swamp, and an occasional shag (Phalacrocorax carbo) passes from stream to stream. The black-cap tern (Sterna albistriata) and the seagull (Larus dominions) are rather common on the river-beds. Of native land-birds the grey warbler (Pseudogerygone igata) is the com- monest in shrub-land and forest-skirt. The kea (Nestor notabilis) occurs in flocks of ten to twenty above the line of about 4,000 ft., and traces of its scratching for earth-boring insects are frequently seen. The banded dotterel (Ochthodromus bicinctus) is common on the river-beds, an occasional hawk (Circus gouldi) nests in the swamps, and very rarely a morepork (Ninox novae-zealandiae) may be heard from the patches of forest. Introduced birds are much more numerous. The skylark (Alauda arvensis) is found everywhere, and a nest with eggs was seen among the rocks at an elevation of nearly 5,000 ft. Skylarks are in this locality almost purely insectivorous, though in the agricultural districts poisoned grain scattered over a field of sprouting wheat kills more larks than sparrows. The house-sparrow (Passer domesticus) and starling (Sturnus vulgaris) build about the railway- station, but, while the sparrow keeps near the buildings, the starling may be seen a mile away on the rocks and the tussock-land. Thrushes (Turdus musicus), blackbirds (T. merula), red-poll1- (Linota nifescens), and, most of all, yellowhammers (Emberiza citrinella) have invaded the shrub-land, and doubtless exert a considerable effect on the insect-life. Tt seems likely that birds were once much more numerous than they are at present. This opinion is based upon two facts : (1) The development of protective coloration among all orders of insects is very perfect, and seems much more elaborate than is necessary to escape the meagre army of enemies now present. Further, many insects are abandoning (or, it may be. had never acquired) the habits that would conduce to safety from bird-attack. Cramhus flexuosellus, the common yellowy-white moth of the tussocks, is a familiar example. While stationary it is invisible, but it rises before the walker at every step, and its movement when disturbed tiiLGENuoRF. — Insect-life at Cans Mountain Biological Station. 137 would soon lead to its extermination if there were a hungry insectivorous- bird population. The highly protectively coloured Scoparia philerga of the forest-glades is quite invisible as it sits at rest on the trunks of the beech-trees, but if one walks noisily forward the moth will fill the air in its fluttering hundreds. It is true that in both these cases the kind of noise demanded is not that associated with a bird-attack, and the short zigzasf flight and quick settling may lead to escape from other dangers. Still, protective coloration and the crouching habit are nearly always associated, and in many insects at Cass that association does not exist. (2) The second fact indicating a more plentiful bird-life in the past is the great profusion of berries and drupes borne by the shrubs. The close connection between the presence of birds and the production of succulent fruits is denied by Guppy,* bat his views do not appear to have received wide acceptance. The writer's view is that if there were no frugiverous animals, then the characteristic of producing brightly coloured, fleshy, and palatable fruits would not have been fixed in so high a degree as is commonly found, and that a large number of plants bearing such fruits is evidence of a large bird population. The suggestion that frugiverous birds would have no effect on the insect-life is of little weight, as the annual variation in the food of birds is not well known. The variation is probably considerable, as is indicated by the fact that so purely a grain-eating bird as the sparrow feeds its nestlings for about six weeks on nothing but insects. Of more import- ance is the suggestion that the birds probably visited certain districts only during the fruiting season of the plants they specially favoured, and at that time would almost entirely neglect insects as food. Except the birds, the only native land vertebrate is the common lizard {Lygosoma moco), which is found not infrequently on the tussock. In the lakes and streams, however, fish, especially trout, are very common, and the introduction of trout must have made an enormous difference to the insect and probably to the bird population of the district. Hudsonf has shown that the stomachs of 60 trout taken from various localities contained 4,804 Neuroptera, 662 other insects, and 28 other animals. At this rate the reduction of Neuroptera in our streams must be enormous, and, as these insects, while aquatic in their immature stages, are aerial when adult, insect-eating birds may also have suffered a reduction in food-supplies sufficient either to drive them from the neighbourhood or at least to compel them to take to other food. In either case the reaction upon the general insect-life of the district must have been very considerable, and it becomes obvious that the insects are, on the whole, living in an environment that is much changed since the advent of the white man. Two important factors in the environment are dead sheep and white flowers, for these are correlated with the two most striking features of the insect-life — namely, blow-flies by day and moths by night. The two com- mon blow-flies are Calliphora quadrimaculata, the well-known bluebottle, and C. oceana, which is somewhat smaller, and is covered with bright- yellow hairs below. Both these species occur in hundreds everywhere, and fill the air with their buzzing wherever a human being rests for a few minutes. When a sheen dies the blow-flies are attracted from near and far : each lays a hundred or more eggs upon it, and the resultant maggots are fully fed through their active life. But the thousands of flies thus * H. B. Guppy, Observations of a Naturalist in the Pacific, vol. 2, p. 99, 1906. t O. V. Hudson, New Zealand Neuroptera, West and Newman, London, 1904. 138 Transact tons. produced do not always find a dead sheep on which to lay their eggs, and therefore they are urgently attracted to any place where there is the faintest scent of animal matter. I have seen C. quadrimaculata so violently impelled to lay her eggs somewhere that she has done so on a bicycle-tire where it had just been pressed with a perspiring hand. After nightfall the swarms of moths are as insistent as are the blow- flies by day. These night-flying honey-suckers are represented by about twenty species, and, as these were obtained chiefly round the lamp in the living-room of the station, definite search would probably double the number of species. Now, the day-flying honey-suckers number only eight species, and the disproportion in individuals is much greater. The entomophilous flowers of the neighbourhood, therefore, must depend chiefly upon night- flying insects, and the colours of their flowers should be most commonly white, or some pale tint, rather than the darker colours of red, blue, or deep yellow. An examination was made of the list of plants near the station as given by Cockayne and Foweraker, and the colours of such of them as produce nectar were taken from Cheeseman's Manual of the New Zealand Flora. The examination showed that fifty-one native plants were described as having flowers either white, rosy white, or pale blue or white, while only sixteen were described as yellow, red, blue, or brown. Dr. Cockayne has pointed out to me the undeniable fact that, to the human eye at least, white flowers are much more conspicuous even by day than those of any other colour, so that it would probably be quite incorrect to regard every white flower as cross-fertilized by night-flying insects. At the same time, given the nocturnal or crepuscular honey-suckers, it would obviously be advan- tageous for the plant to have white flowers : abundance of such flowers would encourage the multiplication of the insects that depend on them for their food; so that the large excess of plants bearing white or pale flowers is here regarded as an important factor in the character of the insect population. B. The Insect-associations. The above term has been used to indicate that, as the plants of the area are grouped into definite associations depending on environmental con- ditions, so the insects are grouped together according to their environment, of which, of course, the plant-covering is the most important factor. The insect-associations have been named more or less closely after the plant- associations, partly to avoid multiplication of names, and partly because the plant-covering is more conspicuous and forms the determining factor in the character of the insect-association. The range of species in an insect- association is, of course, not so clear-cut as in the plant-associations ; for, while one may be able to say to a yard where tussock ends and swamp begins, the insects proper to one kind of environment may be found flying over the plants of another — as, for instance, when dragon-flies or sand- flies are found on the tussock. Again, insects that feed on the plants of one association may take shelter in another, as in the case of numerous moths which probably feed on the flowers of the shrub-land, but shelter by day in the forest, or may be attracted by night to a light on the tussock. The variety of plant-associations in close proximity to the station is a great advantage from most points of view, but in the present instance may lead to some errors in assigning certain insects to their proper associations. Hilgendorf. — Insect-life at Cass Mountain Biological Station. 139 1. The Tussock Grass-land. Large numbers of yellowish-white moths rise from the tussocks at every step. These are chiefly Grambus flexuosellus, but Scoparia salbulosella is almost equally common. Crambus simplex and ('. ramosellus also occur. These all have a wing-span of about 23 mm., and the Scoparia has pale- grey front wings. The metallic-blue butterfly Chrysophanus boldenarum, of 22 mm. wing-span, nutters about the open spaces a few inches from the ground, and sinks from sight as it folds its wings over its back and displays only their mottled-grey undersides. The large attractive butterfly Argyro- phenga antipodum flies lazily or sports merrily, usually in pairs, a few feet from the ground. This insect displays one of our best examples of pro- tective coloration adapted to a special environment. The expanse of the wings is 45 mm., and their upper surfaces as well as the lower surfaces of the front pair have a rich brown background with bold orange masses, picked out with black and white spots. The remaining surfaces — namely, the lower ones of the back wings — have a buff background with longitudinal bright-silver stripes. The insect is most conspicuous while on the wing, but as soon as it settles on a tussock, its invariable resting-place, it becomes quite invisible : it exposes the buff and silver surfaces of its wings, which harmonize with the leaves of the tussock to an almost incredible degree of exactness. Occasionally Chrysophanus salustius, a yellow and black butter- fly of 27 mm. wing-spread, may be seen flying low down, especially near the shrub-land, and a few moths of the night may be accidentally disturbed. The blow-flies will always be hovering round, and the eye will be caught by the furtive flights of several other Diptera, usually protectively coloured. The repulsive bristly Hystricia pachyprocta, with a stout yellow body 15 mm. in length, and the somewhat smaller Macquartia kumaraensis and M. subtilis, often remain stationary long . enough to permit of observation ; while the darting Limnia striata, 7 mm. long, and with curiously mottled wings, will usually require a grab with the hand to effect its capture. Two smaller flies that will hardly be noticed may be captured in scores by walking along with a net held near the surface of the tussock. One of these is probablv an undescribed species of Trypeta, and the other may be a representative of a new genus of the family Dexiidae. Itamus varius, a predatory fly, 17 mm. in length, is very common. Among the Hymenoptera the attractive Ichneumon solicitorius , with a yellow and black parti-coloured body, 15 mm. long, is frequently seen. Lissonota flavopicta, 10 mm. in length, with an ovipositor as long again, also occurs, as well as two other ichneumons that have not so far been identified. The common native bee, Dasycolletes hirticeps, with its bright- golden hairs on thorax and legs, is commonly seen working among the flowers of the introduced Hypochaeris radicata, and probably assists in the spread of this weed, which is the commonest introduced plant on the tussock-land. It may be noted here, for as far as it bears on insect-life, that this plant opens its flowers only from 8.30 a.m. till 3.30 p.m. even on the longest and most sunshiny days of the year. Another bee, 9 mm. in length, black but with downy white hairs on the thorax, also occurs on the tussock, but has not so far been identified. Specimens of the Coleoptera are not common. Down on the ground our handsome metallic black and green Trichosternus antarcticus, up to 30 mm. long, may be seen hurrying along, and dead specimens may be found in scores or hundreds lying on the gravel between the railway-lines. As this beetle is incapable of flight, it is diffi- cult to see how it manages to climb over the rails, or how, once having 140 Transaction*. got between them, it cannot get out again. Six specimens of a new and handsome species of Mecodema, bright shining black and 25 mm. in length. have also been taken crawling along among the tussocks, as well as a few specimens of the handsome Nascio enysi, 9 mm. long, black with four large yellow spots, and the less common Aemona separata, a large pale - yellowish • brown beetle, and the small black Anchomenus feredayi. On clayey banks among the tussock Cicindela feredayi, or a closely allied species, with an intricate yellow edging to its brownish - black elytra, darts in and out of its holes in the ground or takes short nights to elude capture. The only Orthoptera noted are the common grasshopper, Phaidacridiam margin-ale, which varies in colour from brown to green but always has a pair of white lines along the sides of the back of the thorax, and Paprides australis. Members of the other orders are not common. The cicada Melampsalta nervosa is more frequently heard than seen, and one of the Coccidae sometimes produces a striking appearance in the heart of the wild-spaniard (Aciphylla squarrosa). At first glance it appears as if a cup of flour had been emptied into the centre of the rosette of leaves, but on examination this is seen to be the waxy excretion of Pseudococcus oamaruensis, living specimens of which may be seen crawling among the mass of mealy powder. Anywhere near the swamps sand-flies are bound to occur, and an occasional dragon-fly may dart past. Here also must be mentioned three introduced insects : the house-fly, which occurs sparingly indoors ; the European earwig (Forficula auricularia), which is very common under boards, &c, lying round the railway-station buildings ; and the sheep's nasal bot-fly (Oestrus ovis), which lays its eggs in the sheep's nostrils. 2. The Lake and Swamp. In the shallow water near the edge of the lake the water-boatman (Anisops) occurs freely, darting up to the surface for air and clown again to feed. In the same position the larvae and nymphs of most of the dragon- flies may be found, but they are so effectively protected by their trans- parency or greenish tints th; t they easily escape observation despite their length of 20 mm. or over. In the swamp round the lake and lower down the Grassmere Stream the dragon-flies are the most conspicuous insects. The largest is Uropetala carovei, which is 8 cm. or 9 cm. in length and 10 cm. or 11 cm. in wing-span. As well as being the largest it is the rarest of the dragon-flies, perhaps because its larva and nymph, which is found in Lake Sarah up to 4-5 cm. long, must afford such suitable food for the large trout which abound there. This dragon-fly shows in perfection the habit of many of the .species in frequenting a favourite spot over which it ranges in its hawking flights. Besides the swamps it is common on the rock-faces that border the Waimakariri. Next in size and frequency is Somatochlora smithii, 4-5 cm. in length and 6 cm. in wing-span. The thorax is metallic green, and in the male the proximal segments of the abdomen are of reduced diameter. This species dives into the water of smooth pools and picks off the surface floating larvae of certain gnats. It appears to wet only its head, and may make ten or twenty dives in a minute. Lestes colensonis, A . T. Lissonota flavopicta. T. Gasteruption flavipes. Sh. Order Coleoptera. Pyronota f estiva. Sh. P. sobrina. Sh. Aemona separata. T. Nascio enysi. T. Vedalia cardinalis. Sh. Order Lepidoptera. Nyctemera annolata. T. Orthosia comma. T. (?) Physetica coerulea. T. (?) Leucania propria. T. (?) L.nullifera. T. (?) L. acontistis. T. (?) Melanchra compositis. T. (?) M. insignis. T. (?) Agrotis ypsilon. T. (?) Hydriomena deltoidata. F. T. (?) FewMsm undosata. T. (?) Asaphodes megaspilata. F. (?) Xantkorhoe rosearia. T. (?) X. clarata. S. (?) Dasyurus anceps. R. Notoreas ferox. R. T. T. T. Sestra humeraria. T. (?) ^4 }*<7^ / ophenga antipodum . Chrysophanus salustius. C. boldenarum. T. Scoparia philerga. F. /S. salbulosella. T. Plat ipt ilia falcatilis. Crambus flexuosellus. C. simplex. T. C. ramosellus. T. C. xaaihogrammus. R. Oeceticus omnivorus. F. Hannologa p. R. Proteod.es carnifex. T. (?) Palaeomicra zonodoxa. F. (?) Porina umbraculata. T. (?) Order Diptera. Mycetophilus fagi. F. Chironomus zealandicus. S. Tipula obscuripennis. S. T. novarae. S. T. sp. S. Simulium australense. S. Ryphns sp. T. Anabarhynchus innotatus. R. Itamus varius. T. Limnia striata. T. Trypeta sp. T. R. Macquartia kumaraensis . M. subtilis. T. M. sp. R. Hystricia pachyprocta. T. Calcager apertum. T. Species of fam. Dexiidae. Calliphora quadrimaculata. C. oceana. T. Musca domestica. T. Oestrus ovis. T. T. Order Hemiptera. Anisops wakefieldi. L. j Pseudococcus oamaruensis. Melampsalta nervosa. T. S. T. 144 Transactions. Uropetala caroveA. S. Somatochlora smithii. S. Lestes colensonis. S. Xanthagrion zealandicum. S Coloburiseus humeralis. R. Order Neuroptera. Oniscigaster sp. R. Pseudoeconesus mimus. R. Pseudonema obsoleta. R. F. Hijdrobiosis umbripennis. R. Order Orthoptera. Clitarchus sp. S. Phaulacridiian marginale. Paprides australis. T. Species of Acrid iidae. R. Forficula auriculata. T. Art. XII. — On a Partially White Form of Piiffrmis grisens Gmelin. By D. L. Poppelwell. [Bead before the Otago Institute. 12th June, 1917 ; received by Editors. 22nd December, 1917 : issued separately, 24th May, 1918.] Albinism of a complete or partial nature has several times been reported in connection with New Zealand birds, but the cases of its occurrence are not so frequent but that they should be recorded. On the 26th April, 1916, when returning from a trip to Stewart Island, I was shown by Mr. John Smith, of the Bluff, a live specimen of a mutton-bird (Puffinus griseus) which showed partial albinism. This interesting specimen was captured by Mr. Smith on Piko-mamaku-iti, the most northerly of the Titi Islands, where Mr. Smith was mutton- birding. The bird was a young one, and was caught in a nest. It was almost fully fledged. The head, neck, and upper part of the breast of this interesting specimen were pure white, back and upper part of the wings partly black, abdomen brown, the tail white. The bird, as mentioned above, was a young one, and in parts still had the down attached. Its beak was of a pinkish white, its legs pink, and its eye greenish. I examined the bird closely, and took certain measurements and other particulars, which were as follows : — Inches. Length from tip of beak to butt of tail . . . . 13-50 Length of side of beak Length of beak from tip to nostrils Length of wing from flexure Total length of wing Total spread of wings Length of tarsus Length of middle toe Number of feathers in tail, fourteen 2-25 1-25 12-00 19-00 42-50 2-25 2-75 Note. — The above measurements are, I believe, correct; but, as the bird was alive and resented handling, some difficulty was experienced in Poppelwell. — Partially White Form of Puffinus griseus Gmel. 145 getting some of the measurements exactly. The normal colour of P. griseus is, of course, a sooty brown, the bill horn-colour, and the legs and feet brown. Mr. Smith informed me that partially white mutton-birds are not uncommon, but are yet sufficiently rare as to make a specimen of special interest even to the birders. I had hoped that this specimen would be sent to the Otago Museum, but I understand it has been disposed of privately. As the normal number of feathers in the tail in Puffinus is only twelve, may not the above specimen be a hybrid between Puffinus griseus and some closelv allied genus, such as Priocella. which has fourteen feathers in its tail \ Of course, I may have made a mistake in identification, but the measurements closely accord with P. griseus. We know so little of the habits and life-histories of many of our sea-birds that some such explanation of these abnormal forms seems reasonable. The slight differ- ence in the measurements with those laid down for P. griseus may be thus accounted for. On the 14th June, 1916, I had an interview with Mrs. Sidney Ladbrook, of Mataura, who had just then returned from a birding expedition to Evening Island, off South Cape. She informed me that her party had found a pure-white mutton-bird on the island mentioned, but it was turned loose again. It seems that according to Maori superstition it is an evil omen to catch one of these rare specimens, portending death in the family of the captor. Mrs. Ladbrook informed me also that such a specimen is called a " jimmy bird " if it has white or pink eyes, but if the eyes are black it is known as a " queen bird " and the portent is less serious. The specimen which was caught on the trip just then completed was a pinkish white, but had black eyes. My informant says that these aberrant forms are sometimes found about the same spot in successive years. This latter statement receives corroboration from Mr. J. Bragg, of Half-moon Bay (see p. 38, Cockayne's Report on a Botanical Survey of Stewart Island. Parliamentary Paper C.-12, 1909 : Government Printer). Postscript. Since the above article was written a curious coincidence has occurred which will probably serve to intensify the southern Maori superstition concerning the danger of interfering with a white mutton-bird. The bird referred to by Mrs. Ladbrook was, I understand, caught by her husband. During the birding season of 1917 Mr. and Mrs. Ladbrook went to the same island again, and during a storm two children — a daughter and a niece — whom they had taken with them were washed off the rocks and not seen again. Mrs. Ladbrook informed me that some fear of the result was expressed by the Maoris when the bird was caught. The belief is that the calamity will occur within a year, and in this instance has strangely proved quite accurate. 46 Transactions. Art. XIII. — Notes of a Botanical Visit to Holly ford Valley and Martin's Bay, with a List of Indigenous Plants. By D. L. Poppelwbll and W. A. Thomson. [Read before the Ota go Institute, 12th June, 1917 ; received by Editors, 22nd December, 1017 : issued separately, 24th May. 1918.] During the Christmas holidays of 1916-17 we, in company with some others, paid a visit to Martin's Bay, via the Hollvford Valley. We spent in all about ten days in the locality, examining the vegetation. Owing to lack of time and the difficult nature of the country, we were unable to climb any of the mountains, and consequently our notes relate only to the forest vegetation of Hollvford Valley and that of Martin's Bay itself. No list of the plants of these areas seems to have yet been published, so we append particulars of those seen by us, with some notes as to the ecological conditions and the forest vegetation. Topography and Climate. The Hollvford Valley from the point at which we entered it to the sea at Martin's Bay is about forty miles long. For over twenty miles of this distance it runs almost due north, and is bounded on the west by the Darran Range, which consists of very high and precipitous mountains, varying from 7,000 ft. to 9,000 ft. The principal peaks are Mount Christina (8,675 ft.) and Mount Tutoko (9,042 ft.). On the east side the mountains range from 4,000 ft. to 6,000 ft. in height. The valley is a narrow one, varying from less than a quarter of a mile to about two miles in width. The lower part trends more to the west, and consists of Lake McKerrow, twelve miles long, and a strip of three miles of level land to the sea. The mountains become much lower as the sea is approached. There is little doubt that this valley is subject to a very large rainfall, as is most of the western side of the South Island. The river is increased during its course by many snow-fed streams, which in the spring must be raging torrents. The Pyke River, which drains Lake Alabaster, is the largest of these streams, and is sufficiently deep to require horses to swim even when quite low, as it was at the time of our visit. We do not think this valley is subject to much frost in winter, and can vouch for the fact of great heat in summer. Our party did not experience a single shower during its visit, and from observations taken with the thermometer the shade temperature for several days exceeded 80° F. Where the track meets the valley below Howden Saddle the height above sea-level is between 500 ft. and 600 ft. The fall of the Hollyford River will therefore average about 15 ft. to the mile, although it is much greater in the upper part, as the last fifteen miles (including Lake McKerrow) is tidal. Ecological Conditions. The narrow valley, hemmed in by high mountains, and the high rainfall make the atmosphere warm and humid, and it consequently affords ideal conditions for plant-life. The soil mostly consists of detritus from the mountains, mixed with decaying vegetable matter, and is therefore rich and suitable for rank and rapid growth. The hanging mosses on all the tree-trunks and branches attest the high degree of atmospheric moisture. Poppelwell and W. A. Thomson. — Botany of Hollyford Valley. 147 The hillsides are very steep, and give ample facilities for the growth of both sun- and shade-loving plants. The bush -line ascends to about 2,800 ft. or 3.000 ft. The trees throughout the valley are very high and have fairly close tops, but the high rainfall helps the formation of a stronger under- growth than is usual in beech forests. The Forest Association. Round about Lake Howden the forest is almost entirely a Nothofagus one, but an immediate change is noticeable as soon as the descent to the Hollvford is commenced. The principal beech-trees are Nothofagus Menziesii and N. Solanderi, although N. fusca is found in patches and N. Blairii is also present. Gradually the forest changes as the valley is descended, until the taxads Dacrydium cupressinum, Podocarpus spicatus, and P. fenugineus form a large part of the vegetation. P. Hallii and P. dacrydioides are also found, but do not appear to be anywhere very plentiful in the valley. The undergrowth consists of a second tier of smaller trees, the association being principally Pittosporum, Colensoi, Nothopaiia.r Edgerleyi, Carpodetus serratus, Metrosideros lucida (not abundant), Weinmarj,nia racemosa (comparatively rare), and Griselinia littoralis, with a fair sprinkling of the fern-trees Hemitelia Smiihii and Dicksonia fibrosa, and a considerable growth of Coprosma scrub and ferns. The islands in the river are usually covered with Coriaria ruscifolia. Cordyline australis, and Ann/do conspicua, while Pratia angulaia and Helichrysum bellidioides cover the open spaces. Summary. Perhaps the most interesting of our " finds " are Metrosideros florida Smith, and M . scandens Sol. Freycinetia Banksii A. Cunn. was common at both Martin's Bay and Lake Alabaster. Wahlenbergia eongesta N. E. Brown was noted at Martin's Bay, which adds to the few known habitats of the species. The locality where found and relative abundance of the species are mentioned in the list. The total number of species noted was 226, belonging to 129 genera and 56 families. LIST OF INDIGENOUS PLANTS. PTERIDOPHYTA. Hymenophyllaceae. Trichomanes reniforme Forst. f. Forest ; not uncommon. venosum R. Br. Forest ; rare. Hymenophyllum sanguinolentum (Forst. f.) Sw. Tree-trunks. dilatatum (Forst. f.) Sw. Not very common. ferrugineum Colla. Fairly common. tunbridgense (L.) Sm. On tree-trunks. demissum (Forst. f.) Sw. Not uncommon. fiabellatum, Labill. Not plentiful. Cyatheaceae. Gyathea medullaris (Forst. f.) Sw. Martin's Bay ; somewhat rare. Hemitelia Smithii (Hook, f.) Hook Throughout Alsophila Colensoi Hook. f. Not uncommon. Dicksonia fibrosa Col. Not plentiful. Leptolepia novae-zelandiae (Col.) Kuhn. Head of Hollyford Valley. 148 Transactions. POLYPODIACEAE, Polystichum kispidum (Sw.) J. Sin. Throughout. vestitum (Forst. f.) Presl. Throughout. Lindsaya viridis Col. Rare. Asplenium adiantoides (L.) C. Chi. Near Mid Hut. bidbiferum Forst. f. Common throughout. — — fiaccidum Forst. f. Common on trees. Blechnum Patersoni (R. Br.) Mett. Fairly plentiful. discolor (Forst. f.) Keys. Dry open spaces. — vulcanicum (Bl.) Kuhn. Epiphytic on rocky cliffs. lanceolatum (R. Br.) Sturm. Steep banks. — penna marina (Poir.) Kuhn. Plentiful throughout. - — capense (L.) Schlecht. Abundant. — — fluviatile (R. Br.) Lowe. Not uncommon. Hypolepis tenuifolia (Forst. f.) Bernh. Open spaces. Adiantnm affine Willd. Hidden falls, rocks. Histiopteris incisa (Thbg.) J. Sm. Not abundant. Pteridium esculentum (Forst. f.) Cockayne. Open places only. Polypodium Billardieri (Willd.) C. Chr. Epiphytic on tree-trunks. gramdtidis R. Br. Epiphytic on tree-trunks. — — diver sifolium Willd. Climbing on tree-trunks. Dryopleris pennigera Forst. f. Not uncommon. Cyclophorus serpens (Forst f.) C. Chr. Climbing on trees. G LEICHENIACEAE. Gleichenia dicarpa R. Br. Swampy places. OSMUNDACEAE, Leptopteris hi/menophylloides (A. Rich.) Presl. Fairly common. superba (Col.) Presl. Fairly abundant. Ophioglossiaceae. Botrychium ternatum Sw. Martin's Bay only. Lycopodiaceae. Lycopodium scariosum Forst. f. Not uncommon. volubile Forst. f. Fairly common. Billardieri Spring. Rare. Tmesipteris tannensis Bernh. Not common ; tree-trunks only SPERMOPHYTA. Tax ace ae. Podocarpus Hallii T. Kirk. Not plentiful. nivalis Hook. f. Only at high levels. ferrugineus Don. Common. spicatus R. Br. Plentiful, - dacrydioides A. Rich. Throughout. Dacrydium cupressinum Sol. Fairly abundant throughout. intermedium T. Kirk. Only near Martin's Bay. Colensoi Hook. Martin's Bay only. Phyllocladus alpinus Hook. f. Not uncommon. Poppelwell and W. A. Thomson. — Botany of Holly ford Valley. 149 POTAMOGETONACEAE. Potamogeton Cheesmanii A. Benn. In ponds, &c. SCHEUZERIACEAE. Triglochin striata Ruiz. & Pav. var. jilifolia (Sieb.) Buchen. Wet places, Martin's Bay. Gramineae. Microlaena avenacea (Raoul) Hook. f. Common throughout. Danthonia semiannularis R. Br. var. setifolia Hook. f. Rare ; Hidden Falls. pilosa R. Br. Head of Lake McKerrow. Cunninghamii Hook. f. Not abundant. Arundo conspicua Forst. f. Abundant on islands, &c. Poa Colensoi Hook. f. Cliff-faces. Festuca littoralis Labill. Sand-dunes. Pandanaceae. Freycinetia Banksii A. Cunn. Abundant on creek-banks and at Martin's Bay and Lake Alabaster. Cyperaceae. Scirpus inundatus (R. Br.) Poir. Swampy places, Martin's Bay. nodosus (R. Br.) Rottb. Brackish water. frondosus Banks & Sol. Sand-dunes. Carpha alpina R. Br. Dry heath, Martin's Bay. Gahnia procera Forst. Damp places. — — xanthocarpa Hook. f. (?). Martin's Bay only. Uncinia uncinata (L. f.) Kiiken. Common in forest. Carex ternaria Forst. f. Damp places. lucida Boott. On bush tracks, damp ground. pamila Thbg. Damp sand. Leptocarpus simplex A. Rich. Salt marshes. Juncaceae. Juncus polyanthemos Buchen. Damp places. Liliaceae. Rhipogonum scandens Forst. Not abundant. Enargea parvifiora (Banks & Sol.) Hook. Fairly common. Cordyline australis (Forst. f.) Hook. In Hollyford Valley. ■ indivisa Steud. Rare ; near Howden Saddle. Astelia nervosa Banks & Sol. Very abundant. mordana (T. Kirk) Cockayne. Dry places. Dianella intermedia Endl. Lake McKerrow. Phormium tenax Forst. River-bank. Coohianum Le Jolis. Creek-banks, cliffs, &c. ; common. Iridaceae. Libertia pulchella Spreng. Near Howden Saddle only. ■ ixioides Spreng. Dry places in forest. 331 150 Trans actions. Orchidaceae. Dendrobium Cunninghamii Lindl. Tolerably common. Marina mucronata Lindl. Epiphytic on tree-trunks. autumnalis (Forst. f.) Hook. Epiphytic; not common. Pterostylis Banksii R. Br. In damp forest. Thelymitra longifolia Forst. Martin's Bay. Corysanth.es macrantha Hook. f. Damp banks, &c. ■ — — oblonga Hook. f. Forest-floor. Gastrodia Cunninghamii Hook. f. Beech forest. Bulbophyllum pygmaeum Lindl. Rocks. Martin's Bay. Chloranth ace ae . Ascarina lucida Hook. f. Fairly plentiful; Martin's Bay. Monimiaceae. Hedycarya arborea Forst. Hollyford Valley and Martin's Bar ; common. Fagaceae. Nothofagus fusca (Hook, f.) Oerst. Common. Menziesii (Hook, f.) Oerst. Common. Solanderi (Hook, f.) Oerst. Common. cliffortioides (Hook, f.) Oerst. At higher altitudes. Blairii (T. Kirk) Diels. Not common. Urticaceae. Urtica incisa Poir. Common in forest. ferox Forst. Forest tracks ; plentiful. LORANTHACEAE. Loranthus mieranthus Hook. f. Martin's Bay Elytranthe Colensoi (Hook, f.) Engl. Common on beech-trees. tetrapetalus (Forst. f.) Engl. Common on Vagus; also found on Griselinia. flavida (Hook, f.) Engl. Comparatively rare. POLYGONIACEAE. Bumex neglectus Kirk. Martin's Bay. flexuosus Sol. Martin's Bay. MuehlenbecJcia australis (A. Cunn.) Meissn. Not abundant. complexa (A. Cunn.) Meissn. Fairly common. ■ axillaris Walp. Rare. Caryophyllaceae. Stellaria parviflora Banks & Sol. Open tracks, &c. Colobanthus acicularis Hook. f. Rocks and dry places. Ranunculaceae. Clematis indivisa Willd. Rare. Ranunculus hirtus Banks & Sol. Not uncommon. rivularis Banks & Sol. Martin's Bay. ■ lappaceus Sm. Open spaces, Martin's Bay. Poppet, well and W. A. Thomson. — Botany of Hollyford V alley . 151 Magxoliaceae. Drimi/.s colontta Raoul. Not common. Cruciferae. Cardamine heterophyUa (Forst. f.) 0. E. Schultz var. Forest tracks. Saxifrauaceae. Carpodetus serratus Forst. Fairly plentiful. PlTTOSPORACEAE. Pittosporum Colensoi Hook. f. var. Scattered throughout. CUNONIACEAE. Weinmannia racemosa L. f. Comparatively rare. Rosaceae. Rubus australis Forst. f. Throughout. — cissoides A. Cunn. Not plentiful. subpauperatus Cockayne. Not uncommon. Potentilla anserina (L.) var. anserinoides (Raoul) T. Kirk. Damp places. Acaena novae-zelandiae Kirk. Throughout. — Sanguisorbae Vahl. Common. microphylla Hook. f. On tracks, &c. Geraniaceae. Geranium microphyllum Hook. f. Near Martin's Bay. sessiliflorum Cav. var. Sand-hills. Oxalis magellanica Forst. Near Lake McKerrow. Olacinaceae. Pennantia corymbosa Forst. Not plentiful. Euphorbiaceae. Euphorbia glaaca Forst. f. Sand-dunes only. CORIARIACEAE. Coriaria ruscifolia L. var. Abundant and of great size. thymifolia Humb. & Bonp. var. Fairly plentiful. angustissima Hook. f. Not common. Leguminosae. Sophora tetraptera J. Mull. var. Lake McKerrow and Martin's Bay. Carmichaelia flagelliformis Col. (?). Martin's Bay. Elaeocarpaceae. Aristotelia racemosa (A. Cunn.) Hook. f. Not abundant. Colensoi Hook. f. Rare. fruticosa Hook. f. Common. Elaeocarpus Hookerianus Raoul. Comparatively rare. 152 Transactions. Malvaceae. Hoheria populnea A. Cunn. var. Pyke River. Gay a Lyallii Baker. River- valleys. Violaceae. Viola Cunninghamii Hook. f. . Not uncommon. filicaulis Hook. f. Head of Holly ford Valley ; rare. var. hydrocotyloides (J. B. Armstg.) T. Kirk. Damp tracks. Melicytus ramiflorus Forst. Common throughout. Thymelaeaceae. Pimelea Lyallii Hook. f. Sand-hills, Martin's Bay. Myrtaceae. Leptospermum scoparium Forst. Martin's Bay ; not plentiful. Metrosideros lucida Forst. f. Growing throughout, but local. hypericifolia A. Cunn. Lower Hollyford. florida Sm. Martin's Bay. scandens Sol. Forest, Martin's Bay. Myrtus pedunculata Hook. f. Common. Onagraceae. Epilobium rotmidif olium A. Rich. Bush tracks. — — linnaeoides Hook. f. Open spaces. melanocaulon Hook. f. Creek-beds. — — nummular if olium A. Cunn. var. minimum T. Kirk. Forest. Fuchsia excorticata L. f. Not uncommon. Golensoi Hook. f. Rare. H ALORRHAGACE AE . Halorrhagis erecta (Murr.) Schindler. Sand-hills. Gunnera albocarpa (T. Kirk) Cockayne. Damp places. Araliaceae. Nothopanax simplex (Forst.) Seem. Throughout. Edgerleyi (Hook, f.) Seem. Throughout. Colensoi (Hook, f.) Not plentiful. linearis (Hook, f.) Harms. Near Howden Pass. Pseudopanax crassif olium (Sol.) C. Koch vav. unifoliaium T. Kirk. Not common. Schefflera digitata Forst. Damp situations ; fairly common. Umbelliferae. Hydrocotyle novae-zealandiae DC. Damp places. Apium prostratum Labill. Near sand-hills. filiforme (A. Rich.) Hook. Not uncommon. Anisotome intermedia Hook. f. Rocks and creek-banks, Martin's Bay. CORNACEAE. Griselinia littoralis Raoul. Not uncommon. lucida Forst. Martin's Bay ; not uncommon. Ericaceae. Gaultheria antipoda Forst. f. var. erecta Cheesem. Near Martin's Bay. Poppelwell and W. A. Thomson. — Botany of Hollyford Valley. 153 Epacridaceae. Styphelia acerosa Sol. Martin's Bay and Howden Saddle. - Fraseri (A. Cunn.) F. Mnell. ' Martin's Bay. Archeria Traversii Hook. f. Bare. DracophyUum longifolium (Forst. f.) B. Br. Not plentiful. Myrsinaceae. Suttonia divaricata (A. Cunn.) Hook. f. Throughout. Rapanea Urvillei (A. DC.) Mez. Bare. Convolvulaceae. Calystegia tuguriorum (Forst. f.) B. Br. Bear of sand-hills. sepium B. Br. (?). Near sand-hills. Soldcmella B. Br. On sand, Martin's Bar. BORAGINACEAE. Myosotis Lyallii Hook. f. (?). Bush tracks. Labiatae. Mentha Ounninghamii Benth. Bush tracks. SCROPHUL ARIN ACE AE . Veronica salicifolia Forst. Common ; creek-banks. ■ subalpina Cockayne. Creek-banks. leiophylla Cheesem. (?). Hidden Falls ; not common. Lyallii Hook. f. Not uncommon. catarractae Forst. Hidden Falls. buxifolia Benth. Bare. Ourisia caespitosa Hook. f. Near Howden Saddle Bubiaceae. Coprosma lucida Forst. Common throughout. parviflora Hook. f. Fairly plentiful. — — acerosa A. Cunn. var. arenaria T. Kirk. Dunes. — — foetidissima Forst. Common in forest. rotundifolia A. Cunn. In forest. areolata Cheesem. In forest. Nertera dichondraefolia (A. Cunn.) Hook. Common. depressa Banks & Sol. Comparatively rare. Campanul ace ae . Pratia angulata (Forst. f.) Hook. f. Common. variety with small leaf. In forest. Wahlenbergia albomarginata Hook. Open spaces. congesta (Cheesem.) N. E. Brown. Sand-hills, Martin's Bay. Lobelia anceps L. Wet places, Martin's Bay. Compositae. Lagenophora pumila (Forst. f.) Cheesem. Not uncommon ; Martin's Bay. -* petiolata Hook. f. Plentiful. Olearia arborescens (Forst. f.) Cockayne and Laing. Creek-banks. ilicifolia Hook. f. Plentiful. avicenniaefolia Hook. f. Common in places. Celmisia longifolia Cass. var. Not plentiful. 154 Transaction* . Brachycome Sinclairii Hook. f. On tracks. &c. Raoidia glabra Hook. f. Dry places. australis Hook. f. Shingle-beds. Gnaphalium luteo-album L. Not uncommon. Lyallii Hook. f. Rocks. Martin's Bay. Helichrysum bellidioides (Forst. f.) Willd. Not plentiful. Craspedia uniflora Forst. f. var. robusta Hook. f. Common : Martin's Bay. Cotula dioica Hook. f. Open places ; common. Senecio elaeagnifolius Hook. f. Not plentiful. Art. XIV. -Notes of a Botanical Excursion, to Bunkers Island (Stewart Island) . By D. L. Poppelwell. [Read before tin Otago Institute, 12th June. 1917 ; received by Editor*. 22nd December, 1917: issued separately, '24tlt May, 1918.1 On the 7th April, 1917, in company with Mr. 0. Biggar, of Croydon, I paid a visit to Bunkers, one of the group of islands off the north-east coast of Stewart Island. This scrap of land lies to the eastward of Herekopere, and is one of the Fancy Group. It is only about 700 metres long, with an average width of less than 100 metres. The highest point above sea-level is about 35 metres. The eastern end is a separate island at high tide, and in another part the island is almost cut in two hy the action of the sea. The geological formation consists of rotten granite, a good deal of it being simply a sort of gritty clay. The sea has eaten into this soft material on the southern side, with the result that there are several slips and cliffs there, all of which show much recent denudation. Mr. C. Hansen, of Half-moon Bay, informs me that there is comparatively shallow water on the south and south-west of the island, which suggests that at no distant date the island Avas larger than at present. Ecological Conditions. In common with all other islands of the Stewart Group, Bunkers is subject to a high rainfall, with high winds, but a comparatively mild and equable temperature. On this island there is only a thin coating of peat. Probably it is on this account that there is but little evidence of bird traffic so far as the burrowing petrels are concerned, although penguins were not uncommon. The edaphic conditions and the exposed situation combine to prevent any extent of forest vegetation, although there are not wanting signs of a one- time forest formation. Probably when the island was larger such a forma- tion existed, but the present plant- covering might be called a " scrub " association. Plaxt-formations. These may be divided under the heads of " scrub " and " rocks and cliffs," but with a view to saving space I do not intend to do more than outline the associations. The physiognomy of the scrub shows a smooth exterior, and has the usual grey-green colour of the Olearia- Senecio association of the Stewart Botanical District. Olearia angustifoUa is the commonest plant near the sea, but Senecio rotundifolia and Veronica elliptica are common. Curious to relate, Olearia Colensoi, so common in similar associations on the islands in the vicinity, appears to be absent. Here and there Stilbocarpa Lyallii is seen in patches, and also the common coastal ferns Asplenium lucidum and Poppelwell. — Botanical Excursion to Bunkers I slain/. 155 A. obtusatum. Here and there are open patches covered with Hlerochloe redolens mixed with Pteridium esculentum and Histiopteris Incisa, and in other places with Arundo conspicua. On the higher portion of the island the principal " shrub " is Olearia arborescens, which grows to the dimensions of a small tree with a thick trunk and much-branched top. Great patches of Poly pod in hi diversifoKum are common under the scrub. The rock and cliff vegetation consists of the usual Poa Aston i. Crassida moschata, Mi/osotis albida, Cijclophorus serpens, Tetragonia trigyna, and Apium prostratum. I do not propose to further describe in detail the plant-associations, but am appending a list of the plants noted, from which it will be seen that a somewhat varied type of plant finds a home on this isolated piece of soil. Conclusion. The list of species shows certain surprises. 1 saw no sign of Olearia Colensoi, so common on many other islands in this locality. Poa foliosa and Senecio Stewartiar. so plentiful on Herekopere, only about a mile distant, were also absent. On the other hand, the presence of Melicytus lanceolatus, Hemitelia Smithii, Weinmaunia racemosa, and the orchids Earina mucro- nata and E. an/ am nails suggest a former forest vegetation, of the destruction of part of which by fire there was some evidence. The total number of species listed is seventy, belonging to fifty-three genera and twenty-eight families. In addition to these, five introduced species were noted. LIST OF PLANTS NOTED. PTERIDOPHYTA. Cyatheaceae. Hemitelia Smithii (Hook, f.) Hook. Alsophila Colensoi Hook. f. PoLYPODIACEAE. Polystichum vestitum (Forst. f.) Presl. Asplenium obtusatum Forst, f. - scleroprium Homb. & Jacq. - lucidum Forst. f. flaceidum Forst. t Blechnum capense (L.) Schlecht. Histiopteris incisa (Tlibg.) J. Sm. Pteridium esculentum (Forst. f.) Cockayne. Polypodium diversifolium Willd. Cyclophorus serpens (Forst. f.) C. Chr. Lycopodiaceak. Lycopodium fastigiatum R. Br. rolubile Forst. f. Billardleri Spring. S PEEMO LJH VTA. Gramineae. Hiewchlo' redolens (Forst. f.) R. Br. Arundo conspicua Forst. f. Poa Astoni Petrie. — caespitosa Forst. f. imbecilla Forst. f. 156 Transactions. Cyperaceae. Scirpus nodosus (R. Br.) Rottb. Uncinia pedicellata Kiiken. (?). JlJNCACEAE. Luzula campestris DC. Liliaceae. Astelia nervosa Banks & Sol. Phormium Cookianum Le Jolis. Orchidaceae. Earina mucronata Lindl. autumnalis (Forst. f.) Hook. Thelymitra longifolia Forst. Prasophyllum Golensoi Hook. f. Polygoxaceae. Muehlenbeckia australis (Hook, f.) Meissn. AlZOACEAE. Tetragonia tiigyna Banks & Sol. Cruciferae. Cardamine heterophylla (Forst. f.) 0. E. Schultz var. Crassulaceae. Crassula moschata Forst. f. Cunoniaceae. Weinmannia racemosa L. f. ROSACEAE. Acaena Sanguisorbae Vahl. var. pusilla Bitter. GrERANIACEAE. Geranium microphyllum Hook. f. Viol ace ae. Melicytus lanceolatus Hook. f. Thymelaeaceae. Pimelea Lyallii Hook. f. Onagraceae. E'pilobium pubens A. Rich. Halorrhagaceae. Halorrhagis erecta (Murr.) SchindJer. Gunnera albocarpa (T. Kirk) Cocka)*ne. Araliaceae. Stilbocarpa Lyallii J. B. Armstrong. Nothopanax Colensoi (Hook, f.) Seem. Poppelwell. — Botanical Excursion to Bunkers Island. L57 Umbelliperae. Hydrocotyle novae-zealandiae DC. Apium prostratum Labill. CORNACEAE. Griselinia littoralis Raoul. Myrsinaceae. Rapanea Urvillei (A. DC.) Mez. C ON VOLV UL ACE AE . Calystegia tuguriorum (Forst. £.) R. Br. BORAGINACEAE. Myosotis albida (T. Kirk) Cheesem. SCROPHULARINACEAE. Veronica elliptica Forst. f. Rubiaceae. Coprosma lucida Forst. f. areolata Cheesem. foetidissima Forst. — acerosa A. Cunn. — parviflora Hook. f. Nertera dichondraefolia (A. Cunn.) Hook. f. depressa Banks & Sol. Campanulaceae. Wahlenbergia gracilis (Forst. f.) A. DC. Compositae. Lagenophora puutila (Forst. f.) Cheesem. Brachycome Thorn soni T. Kirk. Olearia angustijolia Hook. f. __ arborescens (Forst. f.) Cockayne and Laing. Gnaphalium luteo-album L. collinum Labill. Helichrysum bellidioides (Forst. f.) Willd. filicaule Hook, f . Senecio lautus Forst. f. — — rotundifolius Hook. f. Sonchus littoralis (Kirk) Cockayne. I N T RUDU 0 E D P L A X T S. Holcus lanatus L. Poa trivialis Lind. (?). Stellaria media Vill. Brassica oleracea L. Hypochaeris radicata L. 1 58 Transactions. Art. XV. Notes on a Botanical Visit to Coll or Bench Island (Stewart Island). By D. L. Poppelwell. [Read befori tin Otago Institute, 12th -June, 1917 ; received by Editors, 22nd, December, 1917 ; issued separately, 24th May, 1918.'] Ox the 10th April, I'.MT. in company with Mr. G. Biggar, of Croydon. I had the opportunity, by courtesy of Mr. Henry Hansen, of Half-moon Bay, of spending a few hours on the above island — one of those off the north-east coast of Stewart Island, distant about six miles from the mainland, at Half -moon Bay. The whole surface of the island is clad with a close forest and scrub association, which in parts is difficult to get through, and conse- quently my list can hardly be considered exhaustive, but it gives a good idea of the plant-covering. The general characteristics of the coastal scrub of all these outlying islands are very similar. This island, however, contains a forest association something like Pukeokaoka,* differing considerably from both Herekoperef and Bunkers,! which are its nearest neighbours. The top of the island is somewhat broken by a series of undulations, and the chief features of the vegetation are the close coastal scrub, the great quantities of Stilbocarpa Lyallii, and the large groves of Dicksonia squarrosa. The ferns of the forest-floor are of immense size, the fronds of Asplenium bulbiferum and A. falcatum attaining a height of 1-5 metres. Petrels and other burrowing-birds do not seem very plentiful except towards the southern end of the island, but penguins (Megadyptes antipodium) were common at the time of our visit, and appeared to be moulting The influence of these birds on the vegetation must be considerable, both on account of their traffic and by the enrichment of the ground by their droppings. I do not intend further describing the plant-associations in detail, but append a list of species noted. From this it will be seen that these number fifty-four, belonging to thirty-seven genera and twenty-four families. For the first time, I think, Senecio Stewart iae is definitely reported from this island. It is plentiful at the south end, but was not seen elsewhere. LIST OF PLANTS NOTED. PTERIDOPHYTA. Cyatheaceae. Dicksonia squarrosa (Forst. f.) Sw. Hymenopii y llaceae. Hymenophyllum sanguinolentum (Forst. f.) Sw. dilatatum (Foist, f.) Sw. Polypodiaceae. demissum (Forst. f.) Sw. Polystichum vestitum (Forst.) Presl. tunbridgense (L.) Sin. — • hispidum (Sw.) Sm. '■' See 1). L. POPPELWELL, Notes on the Plant-covering of Pukeokaoka, Stewart Island. Trans. N.Z. Inst, vol. 48, p. 244. 1916. t See D. L. Poppelwell, Notes of a Botanical Visit to Herekopere Island, Stewart Island, Trans. N.Z. Inst., vol. 47. p. 142, L915. X See article in this volume, p. 1 ">4 Poppelweli.. — Botanical Visit to Coll or Bench Island. 159 PTERIDOPHYTA contimtt d. POLYPODIACEAK continued. Asplenium dbtusatum Forst. f. scleroprium Homb. & Jacq. lucidum Forst. f. bulbiferum Forst. f. — flaccidum Forst. f. falcatwn Lam. Blechnum durum (Moore) C. Chr. penna manna (Poir.) Kuhn. Histiopteris incisa (Thbg.) J. Sm. Polypodia ceae continued. Pic ri s o O o in C • i— I P-, C O C6 hi > o O O cq ./•'«cs! p. mo.] L. Cockayne. — Notes on New Zealand Floristic Botany. 161 Art. XVII. — Notes on New Zealand Floristic Botany, including Descrip- tions of New Species, &c. (No. 3). By L. Cockayne, Ph.D., F.L.S., F.R.S., Hutton and Hector Memorial Medallist. [Rear! before the Wellington Philosophical Society, 24th October. 1917 ; received by Editors, 31st December, 1917 ; issued separately, 30th May, 1918.] Plates IX, X. I. Introduction. In this series of papers, two of which have already appeared,* I am carrying out, as far as lies in my power, the views regarding species and taxonomic procedure expressed in my paper entitled " A Consideration of the Terms ' Species ' and * Variety ' as used in Botany, with Special Reference to the Flora of New Zealand. "f These views are by no means of my own formu- lating. On the contrary, they represent what I believe to be the consensus of opinion of those engaged in the only true way of studying specific distinct- ness— i.e., by means of experiments in genetics according to present-day methods. If my views possess any originality it lies in the method of stating the case and in the proposals suggested for meeting the practical difficulty of making a flora serve its primary purpose of enabling any plant to be readily recognized and accorded its proper name. As the length of the paper cited above and the method of presentation of its arguments may serve to somewhat becloud the practical application of the theories advocated therein, I now briefly state the principles which in this series of papers are the guide for the establishing of species or varieties : — (1.) The starting-point in the setting-up of species is the individual. (2.) Groups of individuals which resemble one another in every character and reproduce their like, subject, of course, to unfixed fluctuat- ing variations, constitute specific units and may be designated " microspecies. "J (3.) One microspecies, if all its related microspecies have been oblite- rated or have never existed, constitutes an invariable or fixed systematic species. Examples : Agathis australis, Veronica cu- pressoides, Epilobium pallidiflorum.§ (4.) Two or more closely related microspecies may be united into a group for the sake of : (a) convenience in identification, (b) em- phasizing the close relationship of minor groups (microspecies), (c) phytogeography. (5.) Such a major group as constituted in (4) forms an aggregate or collective species. (6.) Aggregate species are the " variable species " of floras. Examples : Poa anceps, Ranunculus lappaceus, Pimelea prostrata. (7.) An aggregate species has obviously no real existence ; it is a con- venient abstraction only. * Trans. N.Z. Inst., vol. 48, pp. 193-202, 1916 ; and ibid., vol. 49, pp. 56-65, 1917. t Trans. N.Z. Inst., vol. 49, pp. 66-79. % Other names given to such groups are " biotypes," " petites especes," and " elementary species." § It might well be argued that there are no species which consist of only one micro- species, and that intense study and experiment will demonstrate their polymorphy. 6— Trans. 162 Transactions. (8.) Each microspecies of the combination forming an aggregate species should theoretically receive a varietal name. (9.) But in practice the procedure advocated in (8) would defeat its purpose if the microspecies were too much alike, so in this case groups of virtually identical microspecies can receive varietal rank. (10.) It follows then that, similarly with species, varieties are of two kinds, one reproducing itself true and the other an aggregate. (11.) Aggregate varieties, though abstractions only, so far as the eye goes approximate to true entities. (12.) The description of an aggregate species applies to no special indi- vidual, but includes the striking characters common to all its varieties; obviously, then, there is no "type." 1 13.) If the opinions as given above are accepted, a trinomial nomen- clature becomes necessary, the first name being that of the genus, the second that of the species, and the third that of the variety. (14.) If the opinion is held that every microspecies has been at one time related closely to other microspecies, it follows that even the in- variable species mentioned in (3) should be given varietal names. But this procedure seems unnecessary, and perhaps mischievous, since a binomial for such species is convenient and it indicates that the specific group stands apart from all others.* (15.) In certain cases groups, otherwise well defined, seem to be united by " intermediates " which cannot be joined to such groups or made into one or more species. Such " intermediates," according to the teachings of genetics, may be assumed to be hybrids be- tween microspecies, and their occurrence should not forbid the separation into species or varieties, as the case may be, of the distinct true-breeding groups (microspecies) which are connected by such presumably hybrid intermediates. f As a botanical ecologist, endeavouring to define and classify the plant- communities of New Zealand and to learn something about the physiological requirements of the species and the physiology of form, I have keenly felt, for many years, the want of names for many well-marked groups of indi- viduals which, though fitting fairly well into one or other of the recognized aggregate species, differ so greatly in their ecological requirements from other members of the species to which they are referred that to call them by the same name is most misleading, and in no few instances will cause incorrect ecological deductions.t * Of course, as at present accepted, there are many different degrees of specific isolation, but it should be possible to gradually bring about greater uniformity in this regard. f This has frequently been done in the New Zealand flora, but not because of any special biological explanation such as that of microspecific hybrids. Celmisia discolor and C. incana (Manual, pp. 304-5), Gna/phalium Lyallii and G. trinerve (Manual, p. 323), and many species of Veronica are cases in point. On the other hand, distinct micro- species are denied specific rank owing to their being connected by " intermediates." Examples are : Epilobium pedunculare reduced to a var. of E. nummular if oliuiii (Manual. p. 180), the treatment of the groups included under Huheria populnea (Manual, p. 7!l). and the retention of vars. robusta, minor, and lanata as varieties of Craspedia uniflora (Manual, p. 348). J Of what value would be an account of the leaf-anatomy or the rate of transpiration in the leaves of certain individuals of Pittosporum tenuifolium, Acaena Sanguisorbae, Aristolelia fruticosa, Geranium sessiliflorum, Celmisia coriacea, and Myosotis antarcfica under the above specific names, unless a description of the actual plants dealt with were given — i.e., unless they were accorded for the time being the status of microspecies ? L. Cockayne. — Notes on New Zealand Floristic Botany. 163 It may well be argued that the trend of botanical taxonomy the world over is to bestow specific names on the varieties, thus breaking up the long- recognized aggregates into so-called " valid species." Certainly such groups distinguished by binomials are convenient for the ecologist working at synecology, but they are of far less use to the autecologist, the floristic phytogeographer, or the student of evolution or genetics than are aggre- gates with their varieties distinguished by trinomials. Once cease to empha- size the genetic aspect of taxonomy, away goes its philosophy — indeed, it ceases to be a science ! To apply the principles enumerated above is far from easy ; they pro- bably represent ideals impossible of full attainment. Research is demanded in many directions ; above all, living material is essential — field observa- tions as accurate as possible must be made, and experiments in the garden must finally decide those doubtful points impossible to be solved either in the field or the herbarium. With regard to the species, &c, dealt with in the present paper I have received valuable assistance from various sources without which the work could not have been carried on. I must especially thank Mr. H. H. Allan, M.A., F.L.S. (Ashburton) ; Mr. B. C. Aston, F.I.C. (Wellington) ; Mr. H. Carse (Kaiaka) ; Mr. C. E. Christensen (Hanmer) ; Miss E. M. Herriott, M.A. (Christchurch); the Rev. J. E. Holloway, D.Sc. (Hokitika) ; Mr. R. M. Laing, M.A.. B.Sc. (Christchurch) ; Messrs. Nairn and Son (Christ- church) ; Mr. D. Petrie, M.A. (Auckland) ; Mr. R. H. Rockel, M.A. (New Plymouth) ; Professor A. Wall, M.A. (Christchurch) ; and Mr. J. Young (Christchurch) — all of whom have given me much-valued aid both in material and information. I must also acknowledge the kindness of Pro- fessor H. B. Kirk, M.A. (Wellington), who has afforded me every facility for using the herbarium of the late Mr. T. Kirk, F.L S. ; of Dr. J. A. Thomson for similar privileges with regard to Colenso's herbarium in the Dominion Museum ; and of Mr. A. Turnbull, F.L.S., who has allowed me to consult his splendid library of Australasian and Pacific literature. As far as possible I have deposited in the herbarium of the Canterbury Museum, Christchurch, type specimens of all the species, &c, dealt with in this series of papers. II. Taxonomic. 25.* Carmichaelia Fieldii Cockayne sp. nov. Frutex parvus, glaber, afoliatus nisi juventute, prostratus. Rami usque ad 40 cm. longi sed saepe multo breviores, 2 mm. lati, arcuati, compressi, striati, pauciramosi, cortice luteo-viride obtecti. Racemi brevissimi, nun- quam fasciculati, 2-5 flori ; pedicelli + 3 mm. longi, glabri. Flores non visi. Legumen 3-4 mm. longum, oblique-ovoideum vel -oblongum, quam maxime turgidum, subrugosum, nigrum ; rostrum basi crassum, curvatum, apiculatum. Semina 2-5 (plerumque 3-4), pallide brunnea. South Island : North-western Botanical District — Growing as a small colony on a wind-swept sandstone ledge on a small island rising, at low water, out of the mud-flat of Westhaven (West Wanganui). W. H. Field and B.C. Aston ! The above description is drawn up from insufficient material. In many cases the capsules were much damaged. Carmichaelia Fieldii appears to come nearest in affinity to C. juncea Col., but it differs in its prostrate habit, broader always more or less * The numbers follow on consecutively in this series of papers. 164 Transactions. compressed branchlets, shorter fewer-flowered, racemes, glabrous pedicels, and smaller dehiscent pod, with much stouter beak, which contains not 1-3 but 2-5 seeds. From Carmichaelia prona, the only purely prostrate species yet described, it is distinguished at once by its leafless adult branches, dehiscing pod with longer beak and greater number of seeds. Except for the dehiscence of the pod, the species under consideration would come into the subgenus Huttonella. The plant was discovered by Mr. W. H. Field, M.P., to whom it is dedicated. Mr. Aston was with Mr. Field at the time of the discovery, and he kindly handed over to me for publication the material he had col- lected, gave me two living plants for cultivation and further observation, and supplied the information given above regarding the habitat and habit of the species. 26. Carmichaelia grandiflora (Benth.) Hook. f. var. alba T. Kirk. The var. alba of Carmichaelia grandiflora was established in 1899 by T. Kirk to accommodate a plant which grows abundantly near the out- skirts of subalpine Nothofagus forest in the neighbourhood of the junction of the White River and the main branch of the River Waimakariri, not far from their sources (Western Botanical District). There it has been collected by Kirk himself, Cheeseman, Wall, myself, and others. Cheeseman (Manual, p. 115) recognizes only the " type ': —obviously a mixture — and var. divari- cata T. Kirk, but (Illustrations of the New Zealand Flora, facing pi. 33) he writes regarding C. grandiflora. " It is an exceedingly variable plant. Mr. T. Kirk in his ' Students' Flora,' enumerates three varieties, and there are other distinct-looking forms. These varieties* differ in size, in the mode of branching, and in the size and shape of the pod. But before their systematic position can be properly understood they all require careful study and examination in the field." From this it is evident that, according to Cheeseman, the " varieties " of C. grandiflora differ from one another in virtually all the essential characters used to define the species of Carmichaelia. Coming to var. alba, this is probably now accepted by Cheeseman as o variety, since in the Illustrations, when criticizing Kirk's remarks about its odour, Cheeseman writes, " Mr. T. Kirk in the ' Students' Handbook ' says that the flowers 'smell disgustingly of mice.' But this peculiarity, so far as my own observations go, is only noticeable when the plant is being dried. In the fresh state the odour of the flowers is decidedly pleasant." Since there is blossoming just now in my garden (30th December, 1917) a plant of the variety under consideration, collected for me last year by Professor A. Wall, M.A., from the original locality of the plant, I am in a position to add a few details about the variety from living material, which, unless being slightly less luxuriant and blooming more scantily, is essentially the same as if gathered from a wild plant. Kirk describes his var. alba as follows : " Branchlets more robust, compressed, deeply grooved, fastigiate or nearly so. Flowers as in the typical form, but white. Ripe pods not seen. Smells disgustingly of mice " ; and he adds that it is " possibly a distinct species." The plant in my garden is certainly not " fastigiate " ; on the contrary, the branches are wide-spreading, being 60 cm. in their spread, while the shrub is but 30 cm. high. The branches are dark green, flattened, about * It is not clear whether the author means only Kirk's published varieties or these together with the " other distinct -looking forms," but I think the latter are meant to be included. L. Cockayne. — Notes on New Zealand Floristic Botany. 165 3'5 mm. diameter throughout for their final 15 cm. of length, grooved but not nearly to the same extent as in dried material, and more or less arcuate. The branchlets vary from about 4 cm. to 15 cm. in length ; they are inserted on the flanks of the branch at an angle of about 30° and at about 2'5 cm. distance from one another. They are straight, bright yellowish-green, striate, flat, 3 cm. wide more or less, and almost uniform in width through- out. The leaves are numerous where sheltered, and then in fascicles of 2-4 at the base of young stems ; elsewhere they are inserted in the notch of the stem at an angle similar to that of the insertion of the branchlet ; the largest are about U8 cm. long, 3-foliate, their petiole 7 mm. long and chan- nelled above ; the leaflets are uniform in size, rather dull green, obcordate- cuneate, their midrib sunken above but slightly keeled beneath ; other leaves have similar characters, but they gradually decrease in size towards the tips of the branchlets until they become only 5 mm. long, or even less, and may consist of one leaflet only. In the cultivated plant the leaves are glabrous, but wild specimens show a few hairs on the under-surface, especially on the midrib. By all previous authors C. grandiflora is described as having glabrous leaves, but in all my herbarium specimens collected in various localities, including the classical habitat, Milford Sound, the under- surface of the leaf is more or less hairy, and sometimes considerably so. The flowers are white, except for a distinct pale-purple blotch through the median line of the standard, and honey-scented but rather cloying ; they are in lax-flowered racemes, about 16 mm. long, furnished with short peduncles 4 mm. long or less. The calyx is campanulate and 3 mm. long ; its tube is green or mottled pale purple, and the teeth are acute, small, pale purplish-brown, and ciliolate with white hairs. The standard slightly exceeds the keel, being 6 mm. long by 6 mm. broad ; the wings and keel are equal in length (5-5 mm.). The above description corresponds, as far as changes through drying allow a comparison to be made, with that supplied by dried specimens. The var. alba may therefore be defined as follows : A wide-spreading shrub with the branchlets situated on the flanks of the stems, the racemes numerous, 4-6-flowered, the flowers white with a pale-purple blotch down the centre of the standard and sweet-scented, the standard as broad as long and rather longer than the keel, which equals the wings. Up till now C. grandiflora var. alba has been recorded from its one original station only. But that it has so restricted a distribution seems highly unlikely. It is more than likely that through taxonomists working mainly with dried material the colour of the flowers has been frequently overlooked, and that specimens are now included in herbaria along with the " type," or other possible varieties, which may agree in colour with var. alba. How greatly colour has been neglected in diagnoses of species of Carmichaelia is demonstrated by the facts that Kirk mentions colour specifically in only four out of twenty-three species (Huttonella included) and that Cheeseman refers to colour in only seven out of nineteen species. 27. Carmichaelia juncea Col. ex Hook. f. (var. from Upper Clarence Valley). Carmichaelia juncea Col. was described in the first place by J. D. Hooker in the Flora Novae- Zelandiae, vol. 1, p. 51, from specimens collected by Colenso from " east coast, Hawke's Bay and Taupo." In the Handbook Hooker referred plants from the East Cape (coll. Sinclair), from Akaroa (coll. Raoul), and from the Canterbury Plains (coll. Travers) to this species. 166 Transactions. Petrie in his list of Otago plants (Trans. N.Z. Inst., vol. 28, p. 546, 1896) recorded C. juncea from various localities in what I now call the " North Otago Botanical District." Shortly afterwards, Kirk in the Students' Flora accepted Petrie's determinations, and, as will be seen, enlarged Hooker's original conception of the species. Finally, Cheeseman, in the Manual, followed Kirk, but gave a fuller description of the species than had been published up to that time. Both Kirk and Cheeseman agree in considering that the Otago plant may belong to an undescribed species, basing their opinions chiefly on the size of the pod and position of its beak. On the 9th December, 1917, Mr. Christensen noted a Carmichaelia growing on the bank of the River Clarence (North-eastern Botanical Dis- trict), between the roads leading to Jack's and Jollie's Passes, which he described as "' a bush 2 ft. to 3 ft. in height, with the branches drooping over the water." He very kindly sent me specimens, one showing immature flowers (for the most part) and the other abundance of leaves. Towards the end of the month he again went in quest of fully opened flowers, and sent me a large living specimen fully in bloom, which is now growing in my garden. The above specimens I have been able to compare with Petrie's North Otago plant and with Colenso's type specimens of the species. Below I give a full description of the Clarence Valley plant. It appears to come into the conception of the C. juncea of Cheeseman's Manual, but it differs from both the type and the Otago plant in the racemes never being in fascicles, the glabrous calyx, and the much longer calyx-teeth. I have not yet seen the pod. As for the calyx-teeth, they are different in the three forms. In the type they are so small as to be almost wanting ; in the Otago plant they are small but quite distinct, and broad at the base ; in the Hanmer plant they are comparatively long and narrow. Other distinctions between the three forms may be noted on comparing the following description with Hooker's, Kirk's and Cheeseman's diagnoses. Until fruiting specimens are received, and perhaps comparison made with living material from Hawke's Bay and Otago, which I am hoping to secure, it seems best to let the matter of Carmichaelia juncea remain as Cheeseman has left it. But there seems little doubt that the species as at present constituted is an aggregate, with distinct varieties of restricted distribution. As regards the Akaroa and Canterbury Plains plant I know nothing. Description of Carmichaelia juncea var. from the Upper Clarence Valley. A low shrub 60-90 cm. high, with abundant slender drooping branches and numerous short racemes of small sweet-scented flowers. Branchlets numerous, close-set, passing from stem at a very narrow angle, bright green, compressed, but oldest branches terete, 2-3 mm. broad or rather broader but gradually tapering to an extremely narrow apex, usually leafless, glabrous. Leaves on younger branches, 1-3-foliate, + 16 mm. long, petioles up to 6 mm. long ; leaflets variable in shape and size, frequently oblong or ovate-oblong but occasionally obovate, linear, &c, retuse, bright green, glabrous above but somewhat hairy beneath with short appressed hairs, lateral leaflets much smallest, terminal + 9 mm. long. Racemes solitary, apparently never fascicled, + 6 mm. distant, 4-12-flowered but not dense, up to 12 mm. long ; pedicels and rhachis L. Cockayne. — Notes on New Zealand Floristic Botany. 167 • slightly pubescent especially when young, pedicel at most equalling the calyx, pale-coloured. Flowers minute, about 3-5-4 mm. long; calyx cam- panulate, glabrous, 2 mm. long (to tip of tooth), pale yellowish-cream dotted pale purple, teeth narrow, acute, rather long, dark purple ; standard about 3 mm. long by 4 mm. broad, upper surface cream-coloured on lower half, above dark purple marked with almost black lines passing obliquely from median line of leaf, paler beneath, slightly exceeding the keel ; wings cream-coloured more or less tinged yellow, equalling keel, oblong, rather narrow ; keel near apex dark purple, beneath yellowish to cream-coloured. 28. Carmichaelia Monroi Hook. f. Two years ago Mr. B. C. Aston, F.I.C., while investigating the flora of the Clarence River basin, collected a supposedly undescribed species of Carmichaelia a description of which is given below. The examination of Aston's material led me to a comparison with that in my herbarium of C. Monroi Hook, f., with the result that the Clarence Valley plant may be the true C. Monroi, and that the forms included by Kirk, Cheeseman, and others under that name may be either one or two undescribed species or very distinct varieties of C. Monroi. This conclusion is quite unexpected, for few species in the flora seemed to be better understood than is C. Monroi. Description of Aston s Clarence Valley Species of Carmichaelia. A stout rupestral much-branched shrub with spreading, more or less drooping, leafless branches, up to 60 cm. long. Branchlets rigid, green, flat, grooved, + 12 cm. long and up to 9 mm. wide, hoary pubescent when young with short appressed hairs which also extend at times to the older branchlets. Racemes + 5 cm. long, frequently 7-flowered ; rhachis and pedicels densely pubescent with appressed white hairs ; pedicels slender, about 6 mm. long. Flowers about 10 mm. long. Calyx campanulate, densely hairy, 5 mm. long ; teeth 3 mm. long, narrow-triangular, acute, standard rather longer than the keel, 10 mm. long, 7 mm. broad, ? cream with large purple blotch in centre whence 1 purple lines radiate to margin and apex ; wings 6 mm. long, 2-5 mm. broad, marked with ? purple lines ; keel 9 mm. long, blotched with 1 purple near apex and marked with ? purple lines. Pods 12-17 mm. long, black when ripe, turgid ; valves wrinkled ; beak oblique (straight in one specimen), usually short but up to nearly 3 mm. long ; seeds pale brown mottled with black, rather large, 3 mm. long. South Island : North-eastern Botanical District — On shaded faces of limestone cliffs in various gorges on the south-eastern side of the Inland Kaikoura Mountains. B. C. Aston! Had this limestone-cliff plant been the only species of Carmichaelia in its immediate locality, its altogether different habit, together with its much longer and wider branches and hoary branchlets, its 7-flowered racemes, and its larger flowers, would separate it from any forms of C. Monroi as at present understood. But on stony debris, in close proximity to the rock-plant, but in the open, Mr. Aston collected specimens of a Car- michaelia with short close branchlets like those of C. Monroi of the Manual except that they are pilose as in the rupestral plant. Unfortunately their pods, &c, are too immature in the specimens at my disposal for further comment. The type of Carmichaelia Monroi Hook. f. was collected by Monro " from half-way up to the summit of Macrae's Run " (Awatere River basin) : 168 Transact ion s. Handbook of the N.Z. Flora, p. 49. Hooker's description is very short and inadequate. But the branchlets are described as glabrous, while the flowers are smaller than in the above rupestral plant. Considering that Carmichaelia Monroi Hook. f. and the Clarence Valley plant grow on opposite sides of the same range of mountains, and that the ecological conditions of both areas are not very different, it seems fair to offer the suggestion that perhaps Hooker neglected to note the hairy branchlets of the Awatere plant, and that the groups here discussed are not distinct, but one and the same. But this question can alone be decided by comparing Awatere and Clarence Valley material and growing both rupestral and debris plants from seed and then cultivating the seedlings under identical conditions. Coming next to Carmichaelia Monroi in the sense used by Kirk and Cheeseman, this is invariably a low- growing shrub with dense erect branch- lets forming open flat cushions on stony ground. But an examination of the material of this species at my disposal and a comparison with the descriptions of Hooker, T. Kirk, and Cheeseman respectively have led me to the opinion that more than one varietal group is included. For instance, Petrie's Otago specimens have glabrous calyces — a marked contra- distinction to Hooker's description of his Awatere specimens as having a " hoary " calyx. Also, specimens collected by me in the Eastern Botanical District have almost tomentose calyces, while Cheeseman describes the calyx as " silky, sometimes densely so," but he does not suggest that it is ever glabrous. These Otago specimens, too, have triangular, but not narrow- triangular, calyx-teeth as given by Cheeseman, while the Eastern Botanical District plant has small calyx-teeth. From the above it seems clear that the Otago plant at least should be separated from its allies as a variety, but I do not propose to take this step until the taxonomy of the whole group is made clear. Again, there is an allied but much taller plant than the above cushion- form. This I have collected at Biversdale (Waimakariri Biver basin) and on the Waimakariri River bed on the Canterbury Plain near the protection- works. A specimen was planted by me in the gardens of the Biological Department, Canterbury College, but, unfortunately, before I could describe it, it was killed during the building of the new chemical laboratory. Another living plant was for many years in the old " native section " of the Christ- church Botanical Gardens, and it may still be there. Also, there is in my herbarium, under the MS. name Carmichaelia humilis, a specimen collected by Mr. Petrie in the North Otago Botanical District. To sum up, there is a group of more or less low-growing forms of Carmichaelia closely allied to and including Hooker's original C. Monroi which does not consist of a number of identical individuals, but of minor groups distinguished from one another by well-marked characters, so that the major group is either a collection of closely allied species one of which is Carmichaelia Monroi, or this latter should be treated as an aggregate species consisting of perhaps five quite distinct varieties. 29. Cassinia albida (T. Kirk) Cockayne. In Trans. N.Z. Inst., vol. 38, pp. 368-69, 1906, after considerable experience both with Cassinia Vauvilliersii Hook. f. and the var. albida T. Kirk, I proposed to rank the latter as a species. Cheeseman (Trans. N.Z. Inst., vol. 39, p. 446, 1907), criticizing my procedure, said that the course to be followed in this matter would " depend largely on the point of view and personal judgment of the observer, coupled, of course, with a full consider- L. Cockayne. — Notes on New Zealand Floristic Botany. 169 ation of the evidence available." More recently Cheeseman {Illustrations of the N.Z. Flora, facing pi. 107) accepts C. albida as a species. With my views as to the relations of species and variety greatly changed since 1906, I would now reverse my decision, were it not that both C. Vau- villiersii and C. albida embrace more than one microspecies, and that if the latter were reinstated as a variety of the former it would be necessary to establish subvarieties in addition to varieties, so overburdening the nomenclature. In Trans. N.Z. Inst., loc. cit., a var. canescens of Cassinia albida is defined by me. This is distinguished from the type, to which the distinguishing varietal name " tijpica " is here given,* by the leaf being so densely covered on the upper surface with a mat of white hairs as to look as if powdered with dust or mildew. Some time ago Professor A. Wall sent me living plants of both varieties. These cultivated in my garden have put forth many young shoots, which maintain their distinguishing varietal characters, though in var. canescens the hoariness is somewhat less marked. Both varieties are confined to the North-eastern Botanical District, but recent observations of Wall show that possibly neither variety extends to its southern boundary. In addition to the two varieties dealt with above, Mr. Aston two years ago collected in the Clarence Valley a variety of Cassina albida which is woolly on the under-surface of the leaf and rather more hoary on the upper surface than is var. canescens. But, as I have only the one specimen, I merely call attention to this apparently distinct form. It is a matter of interest that on the Lord Auckland Islands the closely related Cassinia Vauvilliersii (Homb. & Jacq.) Hook. f. is represented by two varieties — viz., the type and one with a canescent upper surface to the leaf. These characters are so striking that the two varieties can be recognized at a distance.f 30. Epilobium chloraefolium Hausskn. This extremely common subalpine species was first described by Hauss- knecht in 1879 from dried material (Oestr. bot. Zeitschrift, vol. 29, p. 149). Although, as Haussknecht points out, the species bears no resemblance to E. rotundifolium Forst. f., the dried material which he examined in various English herbaria showed him that it had been referred to the latter. But long after Haussknecht's subjecting the New Zealand Epilobia to a searching inquiry- -indeed, up to the publication of Kirk's Students' Flora in 1899 — with but few exceptions, the New Zealand Epilobia, now known to number at least thirty-eight species, J as well as some strongly marked varieties, had been crammed into the Procrustean bed of Hooker's arrangement in the Handbook, where but seventeen species were admitted. This summary * Cassinia albida (T. Kirk) Cockayne var. typica Cockayne var. nov. Foliis supra pilis sparsissime obtectis. t See L. Cockayne, The Ecological Botany of the Subantarctic Islands of New Zealand, The Subantarctic Islands of New Zealand, vol. 1, p. 216, 1909. | Since the publication of the twenty-eight species admitted by Cheeseman in the Manual the following have been described either as new or "restored": Epilobium antipodum Petrie, E. arcuatum Petrie, E. cinereum A. Rich, (to replace E. junceum Sol. in part), E. Coclcaynianum Petrie, E. erectum Petrie (to replace E. junceum var. macro- phyllum Hausskn.), E. hirtigerum A. Cunn. (to replace E. junceum var. hirtigerum), E. nerterioides A. Cunn., E. pedunculare A. Cunn., E. rubra- marginatum Cockayne, E. tasmanicum Hausskn. (the last two to replace E. confetiijolium Hook. f. so far as it applied to plants other than those of the New Zealand Subantarctic Botanical Province). 170 Trait mictions. treatment was foi the most part due, I believe, to Hooker's statement m the Handbook (p. 76), as follows : l I have repeatedly studied the New Zealand ones [Epilobia], many of which completely puzzle me. The following descriptions represent in many cases perhaps prevalent forms rather than species ; and the student will certainly find intermediates between most of them. It is useless attempting to name many species until copious suites of specimens are collected, the characters being to a great extent comparative." Cheeseman's description of Epilobium chloraefolium in the Manual is ex- cellent. However, he states (p. 178) that, though a well-marked plant, it is '" at the same time a very variable one, especially in height, degree of branch- ing, size of flowers and capsules, &c." But this variability depends, so far as my investigations go, not upon there being a number of true-breeding races (microspecies) included in either Cheeseman's or Haussknecht's groups, but rather upon true variability according to environment — shade- and sun- plants, for instance, differing greatly in certain particulars. Also, I rather suspect that certain hybrids are included by Cheeseman in his group. In this note I am suggesting an enlargement of the conception of the species by adding a distinct true-breeding group which, although it fits well into the original description if size of organs is ignored, far surpasses the type in this respect. I am also giving a varietal name to the " type," so that to those accepting my conclusions the group E. chloraefolium will consist of the two varieties and of any other allied varieties which may be segregated from the individuals now constituting the species, or in course of time be discovered. (a.) Epilobium chloraefolium Hausskn. var. kaikourense Cockayne var. nov. Habitu robustiore, floribus duplo majoribus a typo differt. This well-marked variety is distinguished at a glance from any form of Epilobium chloraefolium by its exceedingly robust habit and large white flowers, which at times are quite 28 mm. in diameter when fully opened. The stems, decumbent at first, finally erect and woody in their older parts, are stout, purple, shining, smooth, and minutely bifariously pubescent. The leaves are numerous, moderately close-set, pilose especially on the margin at the base and on the petiole when young but finally glabrous, rather thick, coriaceous, somewhat glossy, bright- or yellowish-green above, often reddish beneath, and taper into a short, broad, channelled petiole about 4 mm. long ; the lamina is more or less broadly oblong or even elliptic, about 20 mm. long by 12 mm. wide and distinctly but minutely toothed, its apex is obtuse, the midrib is strongly keeled, and the lateral veins distinct. The flowers are few in the axils of the terminal leaves, white, invariably large, and often attain 28 mm. diameter. The plant continues blooming for more th;m six months. The capsule is about 3-3 cm. long, dark purple, minutely pubescent ; its peduncle is only 3-5 mm. long — i.e., it is much shorter than the subtending leaf, which may be 19 mm. long or longer. The seeds are numerous, + 1-75 mm. long, light-brown, and papillose. The great differences in appearance which the above - described vars. of E. chloraefolium present made me inclined at one time to consider the var. kaikourense a distinct species, especially as it came true from seed and occupied a special limited area of distribution. So long ago as 1892 Mr. T. Kirk wrote to me regarding a specimen (herb. L. Cockayne, No. 3668) I submitted for his opinion, " May prove distinct, but further specimens must be examined — a very interesting form." L. Cockayne. — Notes on New Zealand Floristic Botany. 171 A careful comparison of living plants of both varieties in my garden shows that there is no important difference between them except size, while the structure of the flower is identical in both. The plant was found in the first instance by myself in 1892, growing in rather moist soil on cliffs a little distance from the sea at Kaikoura, and shortly after that I found it to be abundant under the subalpine scrub on Mount Fyffe (Seaward Kaikoura Mountains). Plants were cultivated in my New Brighton garden, where they, or their seedlings, remained for six years at least ; and seeds were sent in 1897, and probably earlier, to various European botanical gardens under the name Epilobium Cockaynianum* Petrie ined., but which Petrie never published. In 1905 Mr. H. J. Matthews and myself again observed the plant on Mount Fyffe, and I recorded its occurrence in Trans. N.Z. Inst., vol. 38, p. 373, 1906, as Epilobium sp. aff. E. chloraefolium Hausskn. Since then the plant in question has been found by Mr. C. E. Foweraker and myself in the Awatere Valley, by Mr. B. C. Aston in the Clarence Valley, and by Professor A. Wall on the Seaward Kaikoura Mountains ; while a plant from Mount Isabel, at Hanmer, collected by Mr. C. E. Christensen probably is var. kaikourense. In other words, the variety is confined to the North-eastern Botanical District, where it is of wide distribution from sea-level to at least 900 m. altitude, and grows on rock, beneath shrubs, and probably in shady tussock grassland. Phytogeographically the distribution of E. chloraefolium var. kaikourense is an interesting case of a true-breeding race of a species of wide distri- bution being confined to a limited area which possesses a special ecological character, as reflected in the great number of locally endemic plants. From the horticultural standpoint, the ease of culture of the plant, its general habit, beautiful long-blooming flowers, and purplish foliage and stems render it worthy of any rock-garden ; nor is there fear of its becoming a weed, as in the case of certain New Zealand Epilobia. (b.) Epilobium chloraefolium Hausskn. var. verum Cockayne var. nov. This equals E. chloraefolium as described by Haussknecht in Mono- graphic der Gattung Epilobium., p. 299, Taf. 19, fig. 81, 1884. No further description is needed. The differences between var. verum and var. kai- kourense are given above. 31. Epilobium pedunculare A. Cunn. var. brunnescens Cockayne var. nov. Caulibus pallidis saepe brunneis tinctis. Foliis ovato-oblongis vel oblongo-rotundatis, supra pallide viridibus saepe brunnescentibus, margine remote dentatis, subtus purpurascentibus. Capsulis glaberrimis, pallide bruneis, + 5-3 cm. longis ; pedicellis colore capsulis etiam, multo elongatis, 6-6 cm. longis. This variety forms large more or less circular patches. The leaves vary in size, but about 9 mm. long is frequent ; the petioles are about 3 mm. long. Where exposed to bright light the leaves assume a brownish tinge. The flowers are small, white, and about 5 mm. diameter. The calyx- segments are narrow-oblong, 3 mm. long, brownish, and end in a swollen purplish apex. The capsule is more than three times the length of the ovary, and the peduncle increases from about 2-2 cm. to 5-7 cm. as the capsule develops. * E. Cockaynianum Petrie in Trans. N.Z. Inst., vol. 41, p. 140, 1909, has no relationship to this, but is related to E. alsinoides A. Cunn. 172 Transactions. Epilobium pedunculare var. brunnescens has a wide range, but this 1 cannot at present define, nor its ecological distribution. However, I have plants in my garden identical in every particular collected from localities far distant from one another — viz., Mount Egmont (coll. L. C.) (Egmont- Wanganui Botanical District) and Four Peaks (coll. A. Wall) (south of the Eastern Botanical District). Haussknecht describes a var. laxa of E. pedunculare, and it may be that my new variety is the same. But without actually comparing the material on which Haussknecht founded his variety it is impossible to come to a conclusion, so it seems to me better to risk the establishment of a synonym, which for a time will serve a definite phytogeographic purpose, than to withhold publication or refer the group to var. laxa, which it may not be after all. The further question arises, am I right to uphold the species Epilobium pedunculare A. Cunn. rather than follow Hooker, Kirk, and Cheeseman, and deal with it as a variety of E. nummularifolium ? Haussknecht — relying only, however, upon dried material — keeps the two species distinct, and strongly supports his position by the two fine figures 94 and 96 {Monographic der Gattung Epilobium, Taf. 22 and 23). He also states that in herbaria E. pedunculare is frequently found mixed with E. nummularifolium, but that they are readily distinguished by E. pedunculare having the leaves smaller, more close-set, thicker, entire, and with shorter stalks ; the capsule glabrous and its peduncle more slender, and the seeds covered much more thickly with papillae (I.e., p. 303 — freely translated). My own experience, after many years' observation of various groups included under the specific names nummularifolium and pedunculare, both growing in many parts of New Zealand and also cultivated by me, has convinced me that the two species are absolutely distinct, and separated by well-marked unchangeable characters. Epilobium nummularifolium, in one form at any rate — and the species may quite well contain only the one form — is common throughout the North and South Islands, but absent in Stewart Island ; it appears to be mainly a lowland plant, but there is no exact record of its distribution, such being confused with that of E. peduncidare, which ascends at least to the subalpine belt. E. nuiitntularifolium may be best distinguished from the aggregate E. pedunculare by its orbicular or suborbicular bright-green leaf with at times a more or less truncate base, its rather long petiole which is winged above, its capsule not glabrous but closely covered with a short (increscent pubescence, its fruiting peduncle not lengthening so greatly as in E. peduncidare, and its less papillose seeds. Even the leaves alone of living specimens enable the two species to be identified in an instant. 32. Epilobium pedunculare A. Cunn. var. minutiflorum Cockayne var. nov. Varietas distinctissima, caulibus gracilibus rubro-purpureis, foliis parvis rotundis subrotundis vel ovatis viridibus, floribus minutis, pedunculis statu fructu solum 3 cm. longis et capsulis purpurascentibus brevibus 11 mm. longis facile distinguenda. South Island: Eastern Botanical District — (1) Trelissick Basin, but details regarding habitat wanting : A. Wall ! (2) Rakaia River bed not far from mouth of river : H. H. Allan ! L. Cockayne. — Notes on New Zealand Floristic Botany, 173 The above variety is described from a plant which has been in my garden for only a few weeks, collected by Professor Wall as above. The plant forms matted patches. The leaves vary in size from less than 3 mm. long up to about 5 mm. The reddish-purple stems, petioles, and peduncles contrast with the bright-green leaves. The flowers are white ; the calyx is pale brown tinged and margined with reddish-purple ; the petals are white ; the slender petiole only increases from 2 cm. to 2-5 cm. when the capsule is ripe. 33. Epilobium pedunculare A. Cunn. var. viride Cockayne var. nov. Oaulibus teneris pallide viridibus ; foliis oblongis vel rotundatis remote et obscure dentatis, laminis usque ad 7 mm. diam. ; floribus 6-5 mm. diam.. pedunculis brevibus 5-11 mm. longis ; capsulis circ. 2-8 cm. longis ; viridibus secundum suturam brunneo tinctis. North Island : North Auckland Botanical District — On river-bed near Fairburn, Mangonui County. H. Carse ! This variety is readily distinguished from E. pedunculare var. brunnescens by its green leaves and. stem and by the much shorter peduncle of the flower, which does not elongate to nearly the same length as that of var. brunnescens in the fruiting stage. The flowers and capsules are also smaller. The plants now growing in my garden, from which the above diagnosis is drawn up, were collected specially for this paper by Mr. H. Carse as an example of the form of Epilobium pedunculare in his neighbourhood. Whether the above variety is identical with the plant originally described by Allan Cunningham I cannot say, for the original description is quite general and would fit almost any variety of the species. 34. Gunnera densiflora Hook. f. In 1864 Hooker published his Gunnera densiflora, basing his description on specimens collected by W. T. L. Travers at an altitude of 4,000 ft. in the Acheron and Clarence Valleys — i.e., it must have been collected not far from the sources of these rivers if the altitude as given is correct. For some thirty-two years no Gunnera was discovered that could be referred to the above species until, in 1896, I collected a species of Gunnera in the Craigie- burn Mountains (Eastern Botanical District), at the headwaters of the Hogsback Creek, at an altitude of rather more than 900 m. Specimens were sent by me to Kirk, who referred them, apparently without hesitation, in his Students' Flora (1899) to G. densiflora. Cheeseman, in the Manual, working with the same material as Kirk, drew up a new diagnosis of the species based partly upon Hooker's original brief description and partly upon my not-too-well-prepared specimens. Regarding these latter Cheese- man writes that they u are the only ones I have seen that can be referred the species." So the matter remained until, in 1911, Mr. R. M. Laing, M.A., B.Sc, during a botanical excursion towards the headwaters of the Rivers Clarence and Waiau, discovered, in abundance, on the western side of Lake Tennyson a species of Gunnera which, in my opinion, is equivalent to the plant on which Hooker founded G. densiflora. Mr. Laing submitted his material first of all to Cheeseman, who sug- gested that it might quite well be Gunnera cordifolia Hook, f., hitherto thought to be confined to Tasmania. Later, Mr. Laing submitted specimens for my opinion, telling me also what Cheeseman had said. G. cordifolia 1 74 Transact ions . is well illustrated in Das Pflanzenreich (IV. 225. Halorrhagaceae, p. 108, fig. 31). After examining Mr. Laing's specimens, and comparing them with the above-cited figure, &c, I came to the conclusion that the species was either G. cordifolia or a variety of that species, and so dealt with it in my unpublished Vegetation of New Zealand. Laing (Trans. N.Z. Inst., vol. 44, pp. 65-66, 1912) drew up a detailed description of the Gunnera in question in the field with the living plant before him, and his and my original opinions are considered below. Regarding the Craigieburn Mountains plant, Laing stated (I.e., p. 66) that Cheeseman had informed him it was distinct from the Lake Tennyson plant, and that it had been identified' by the Kew authorities as Gunnera densiflora Hook. f. Learning recently that Professor Wall intended paying a botanical visit to the Trelissick Basin, I explained to him as exactly as I could — no easy matter — the precise spot where I had collected the Gunnera in 1896, and urged him to make a thorough search. This he most willingly did, and not only found the plant in quantity in the locality indicated, but discovered other stations for it in the neighbourhood. He secured ample material, of which he sent me abundance both living and dried, some of the former being now growing. in my garden. As it is a matter of considerable phyto- geographical importance to get detailed knowledge of this rather critical species of Gunnera I am publishing a description. Description of the Gunnera from the Craigieburn Mountains. Rhizome short, ± 19 mm. long by 5'5 mm. thick, rooting with straight roots about 8 mm. long, and giving off stout, terete, dark-brown, more or less strigose-pilose stolons each about 3 cm. long and 2 mm. diam. Leaves in rosettes of about 4 or 5 + 3"5 cm. across ; petiolate with petiole variable in length from about 2-2-8 cm., fleshy, pale often tinged pink, terete or chan- nelled above or only near junction with lamina, pilose with strigose white hairs on back and margin but variable in this respect as to density of hairs on different leaves of same plant ; lamina moderately bright green, coriaceous, usually more or less cordate at base, sometimes truncate, auricled at base with two small toothed appendages + 2 mm. long which are bent upwards, orbicular or broadly ovate-orbicular, hairy above and on margin, glabrous beneath, rounded at apex or occasionally almost subacute, rather coarsely but sharply toothed with about 9 teeth + 1 mm. long on each side, veins evident above and beneath, midrib stout and keeled beneath. Flowers unisexual, numerous. Male flowers in spikes about 2-5 cm. long terminating rather stout scapes about 2-8 cm. long arising from axils of leaves and densely covered with brown strigose hairs ; pedicels very short, subtended by a small narrow subulate bract about 2 mm. long ; calyx- lobes 2, narrow-triangular, about 1 mm. long ; petals 2, transverse, narrow linear-spathulate, much exceeding anthers, 4 mm. long and 0-5 mm. wide near the black acute apex ; stamens 2, situated on base of petals, broadly ellipsoid, 2 mm. long, rounded at apex, filaments extremely short. Female crowded into a dense globose head about 6 mm. long terminating a stout, fleshy, pale or pale-brown scape 10 mm. long, pilose with numerous white hairs ; calyx-tube urceolate, pale green, smooth, about 2 mm. long ; calyx- lobes 2, subulate, purple with black tip, about 0-75 mm. long. Styles 2, wide-spreading, pale brown, 4-5 mm. long, stigmatic throughout. On compa ing, detail by detail, the above description with that of Laing (for the Lake Tennyson plant), of Schindler (for the Tasmanian plant), L, Cockayne. — Notes on New Zealand Floristic Botany, 175 and of Hooker (for the type of Gunnera densiflora), my opinion is that the New Zealand plants are all one and the same, and that the Tasmanian may also belong to the same species. On the other hand, the New Zealand Gunnera, accepting Schindler's description and illustration of the Tasmanian, differs from the latter in the petals, which are much longer and narrower in the New Zealand than in the Tasmanian plant, and in the shape of the drupe, pyriform in the New Zealand, ovoid according to Hooker ex Schindler in the Tasmanian plant. Also Schindler's figure shows the margin of the leaf of his plant as strongly ciliated, whereas in the New Zealand plants the ciliation is virtually confined to young leaves. Bearing the above in mind, it seems best to maintain Gunnera densiflora as a species, but to remember that it is extremely closely related to G. cordifolia Hook. f. of Tasmania, and is a further link between the floras of the eastern Australian and New Zealand regions. 35. Haastia recurva Hook. f. var. Wallii Cockayne var. nov. Foliis et capitulis quam ilia typi minoribus ; plerumque pilis albidis munitis sed eis prope ramulorum apices interdum subfulvidis tinctis ; bracteis involucri apiculatis. The variety differs from any example of Haastia recurva that I have seen hitherto in the much smaller size of all its parts, in its dense wool being white nearly everywhere and only slightly fulvous near the apices of the branchlets, and in the apiculate apex of the involucral bracts. The leaves are generally less than 10 mm. long, or only half the length of good-sized leaves of the type. The flower-heads are 7 mm. diam., or not half the size of medium-sized heads in the type. The plant was collected by Professor A. Wall on a shingle-slip near the summit of Mount Fyffe, Seaward Kaikoura Mountains. Unfortunately, only the one plant was noted. On receiving the specimen I thought this plant with white wool and slender branches might be the common form of the Kaikoura Mountains in general, but upon comparison with Mr. Aston's specimens from Mount Tapuaenuku (Inland Kaikoura Mountains) this apparently is not the case. Specimens from Shingly Range (Awatere) also belong to the type. 36. Haastia Sinclairii Hook. f. Judging from specimens in my herbarium, there appear to be two dis- tinct groups of plants included under Haastia Sinclairii Hook. f. by Cheese- man (Manual, p. 321). One of these gronps is figured in Cheeseman's Illustrations of the N.Z. Flora, pi. 100, and this appears characteristic of the species so far as the North-western and Western Botanical Districts are concerned ; . but the Fiord Botanical District group appears to differ in certain particulars as compared with the more northern plant, especially in its smaller leaves, which are covered beneath much more thinly with fulvous (not white) wool, and above are thinly covered with wool or, at times, almost glabrous. Also, the heads of the Fiord plant are much smaller. I do not propose here to separate the species into two varieties, the intention of this note being to call the attention of collectors in the area of the species to probable differences in plants of this species which they may find. In the Illustrations of the N.Z. Flora Cheeseman comments upon the distribution of Haastia Sinclairii as follows : " H. Sinclairii, which is a true : shingle-slip ' plant, never found away from the slopes of dry shingle which form such a prominent feature on the eastern 'side of the Southern Alps." 176 Transactions. And farther on— " But it was soon found to have a wide distribution on the eastern side of the Southern Alps, and is now known to extend from the northern portions of the Mount Arthur Range southwards through the Canterbury Alps to the south-west of Otago. ... I am not aware, owever, that it occurs in any locality well on the western side of the watershed of the Alps." The above statements, though topographically true in our present state of knowledge, neglect the ecological viewpoint. There are two distinct classes of shingle-slips — the one very dry on the surface and situated beyond the average limit reached by the western rainfall, and the other not by any means so dry a station, since it lies within the wet area. These two classes of shingle-slip are clearly defined by their plant inhabitants. A dry or eastern shingle-slip contains that wonderful assemblage of which the follow- ing, to cite only a few, are characteristic : Craspedia alpina, Notothlaspi rosulatum, Poa sclerophylla, Ranunculus Haastii, Stellaria Roughii, Veronica epacridea. On the other hand, the western shingle-slip contains none of the above species ; in fact, there are but few plants common to both — e.g., Epilobium pycnostachyum is one. The species of Haastia, too, are an especially good index. On an eastern shingle-slip (using the term ecologically and not as used in the quotation above) Haastia recurva is alone to be found, but on a western shingle-slip it is absent, being repre- sented by H. Sinclairii. So, too, the dry east gives Veronica Haastii, but once well into the area of excessive rain it is V. Haastii var. macrocalyx. As for Haastia Sinclairii not having been found to the west of the actual Divide, I suspect this is chiefly due to the fact that shingle-slip is not much in evidence on the west, speaking comparatively, and also that, the North-western Botanical District excepted, few collections have been made on mountains possessing shingle-slips, these true western mountains being almost entirely unexplored botanically. 37. Hymenanthera crassifolia Hook. f. Hymenanthera crassifolia Hook. f. was originally a mixture of Scaevola novae - zelandiae A. Cunn., now known as Hymenanthera novae-zelandiae (A. Cunn.) Hemsley, and plants from Cape Palliser and Nelson. These latter, along with certain other plants, form H. crassifolia in its restricted sense. But the distribution of the species is uncertain, owing to lack of knowledge as to the limits of polymorphy to be allowed or the variation which takes place not only in H. crassifolia but in the species next dealt with — H. obovata T. Kirk. At any rate, so far as I know, true H. crassifolia is found in the Ruahine- Cook Botanical District, on the coast both of the Wellington and Sounds Subdistricts, whence it extends, but not in an unbroken line, to the coast of the South Otago Botanical District. Certain inland plants have been referred to this species, as also a Stewart Island plant, but all these deter- minations must be received with caution. Although there is an admirable plate of H. crassifolia in the Flora Novae- Zelandiae, there is no description easily available which deals with the colour of the flower, and as this is an important character for identification pur- poses the following description of the flower may prove useful. Description of Flowers of Hymenanthera crassifolia Hook. f. Flowers inserted on under-surface of twigs, numerous but quite hidden from view on living plant, very small, usually solitary but close-set, her- L. Cockayne.— Notes on New Zealand Florist ic Botany. 177 maphrodite, slightly sweet-scented, pedunculate with decurved or straight green peduncle rather shorter than the flower, furnished with two minute, broadly triangular, scarious brown bracts inserted a little below its centre. Sepals orbicular, about one-half length of petals, green with broad, purplish, minutely fimbriate margin. Petals waxy in appearance, lemon - yellow, oblong, + 3 mm. long, obtuse, recurved at apex which on margin is some- times purplish ; in bud deeply stained purple. The pollen is shed just before the flower opens or shortly afterwards and so easily falls on the stigma. There is no honey. Abundance of pollen reaches the stigma. After pollination the ovary, &c, rapidly enlarges. In the neighbourhood of Wellington H. crassifolia commences to bloom some time during the first two weeks of September. 38. Hymenanthera obovata T. Kirk. Hymenanthera obovata, as established by T. Kirk in_1895 (Trans. N.Z. Inst., vol. 27, p. 350), and upheld by Cheeseman in 1906 (Manual, p. 50), is based on material from two sources — the Trelissick Basin (Canterbury) and various localities in Nelson. An examination of the type material in Kirk's herbarium shows that the Trelissick and Nelson material look very different, and the feeling at once arises that the species as at present con- stituted is a combination of two distinct groups of individuals, each of which is entitled to rank as a species. The above difficulty is increased, firstly, by the imperfect knowledge of the flowers of either the Trelissick or Nelson plants, and, secondly, by the discovery by Mr. B. C. Aston, some years ago, of another group of indi- viduals with, it is now known, a local distribution along the shores, &c, of Cook Strait from the French Pass and Kapiti Island to Somes Island in Wellington Harbour. This last-named group far more closely resembles the Nelson than the Trelissick group — indeed, when the flowers of the Nelson group are investigated it possibly will be found either that the two groups are identical, or that they are microspecies which must be united under one name. Likewise, judging from Kirk's type specimens, from my per- sonal knowledge of the genus Hymenanthera in the Trelissick Basin, and from fresh specimens of the plant in question recently collected in the above locality by Professor Wall, it seems not unlikely that the Trelissick group may eventually be referred to H. crassifolia. The present state of knowledge regarding Hymenanthera obovata, which I have attempted to concisely indicate, demands that any further knowledge should at once be made available for students and collectors, so that the real status of the species, and of the groups cited above, may be established. Thanks to Mr. Aston, who last year (1916) put me in the way of seeing the Wellington plant in more than one locality, and who assisted me in col- lecting ample flowering material, I am in a position to describe the Welling- ton plant. Further, Mr. Aston at the close of the year 1917 collected material of the Nelson plant from the Riwaka-Takaka hills, which he has placed in my hands. Finally, Professor Wall has procured for me living and dried material of the Trelissick plant ; while Miss Herriott (Biological Laboratory, Canterbury College) sent me some time ago from Cass (Wai- makariri River basin) seedlings of the Hymenanthera of that locality, which must be either H. obovata T. Kirk (in part) or H. dentata var. alpina, another group of quite uncertain position. 178 Transaction*. Description of the Wellington Coastal Hymenanthera (= ? H. obvata T. Kirk in its restricted sense). A low shrub more or less flattened, to the substratum into which its prostrate stems root, but its height varies with regard to degree of exposure of the plant. Branches more or less divaricating and interlacing, with younger twigs clad with pale bark covered with a fine pubescence, but older twigs having grey bark dotted freely with lenticels. Leaves obovate or oblong-obovate, varying greatly in size according to situation, but from 1 cm. long by 7 mm. wide to 3 cm. long by 1-6 cm. wide are a fair average, though there are others both larger and even smaller, very dark green above, whitish-green beneath, very thick and coriaceous, obtuse, often emarginate, generally entire but occasionally there is a coarse tooth on either side,* above veins obscure, beneath evident but not numerous ; petiole short, about 3 mm. long. (In shade reversion-shoots occur with leaves thinner, larger, more irregular in shape, sometimes rhomboid, 1-2-toothed on either side.) Flowers numerous, about 4 mm. diam., mostly on the naked branches. in the axils of former leaves, solitary or in fascicles of about 4, apparently hermaphrodite, almost twice as large as those of H. crassifolia (see above, No. 37), paler yellow, more urceolate, and margins of petals edged with a bright-purple line ; pedicels about 4 mm. long, pale green, fleshy ; bract broadly triangular, acute ; sepals 4-5 times shorter than petals, much broader than long, green at base but strongly margined with purple, rounded at apex which is fimbriate ; petals linear-oblong or narrow ovate- oblong, about 5 mm. long and 2 mm. broad, pale yellow, obtuse, sometimes emarginate, strongly recurved ; stamens with orange staminal process ; scale (nectary) obovate, slightly praemorse at fimbriate apex, and abundance of honey at base. Apart from the much greater size of the leaves, and, where not exposed to the most powerful wind, the much more open character of growth, the above species is distinguished at once from H. crassifolia by the flowers, which are twice as large, the sepals not half length of petals but only one- third or one-fourth as long, the narrower, longer, pale-yellow not lemon- yellow petals. With regard to Nelson specimens of undoubted Hymenanthera obovala (in the restricted sense), Aston's specimens are from two sources. The first grows " in crevices of limestone rock at from 2,500 ft. to 2,700 ft. on the Riwaka Hill, and 1-3 ft. high " (fide Aston). Specimens of this plant show (as described for the Wellington plant) the leaves linear-obovate to occasionally almost linear, very numerous, alternate or fascicled, from more than 4 cm. long to 1-5 cm. or even less, not thick, probably rather dark green above, pale beneath, tapering into a short petiole, entire, rounded at apex. The second was taken from one plant growing at Golden Bay, near the cement-works. It was a " shrub with trunk about 10 ft. high and pendulous branches growing in shade on limestone country" (fide Aston). This specimen has leaves up to 7-5 cm. long, some are 3 cm. broad, cpiite small leaves are rare. They are bright green above, pale beneath, entire, occasionally emarginate, not in fascicles. Although the two plants just noted differ so far as the leaf is concerned in some particulars from the Wellington plant, such differences are probably *The Manual description reads, "quite entire," but even Kirk's type specimens show some leaves not entire. Trans. N.Z. Inst., Vol. L. Plate IX. w. [J. E. Young, photo. Leptospermum scoparium Leonard Wilson, growing naturally near Port Levy, Banks Peninsula. Face p. 178.] Trans. N.Z. Inst., Vol. L. Plate X. [;/. E. Younij, photo. Flowering branch of Leptospermum scoparium Leonard Wilson, showing the double white flowers. L. Cockayne. — Notes on New Zealand Floristic Botany. 179 entirely environmental. The most interesting point is the greatly reduced leaves present with much larger ones on the Riwaka plant, and such suggest that perhaps the Trelissick Basin plant is, after all, a reduced form. An examination of flowers and fruit can alone settle this interesting point, but I am still inclined to agree with my opinion as stated above -that the Trelissick plant is one species, and that the Riwaka and other Nelson plants should be united with the Wellington plant either as a polymorphic or an epharmonic group. 39. Leptospermum scoparium Forst. (forms with double flowers). (Plates IX and X.) In New Zealand Plants and their Story, p. 149 (1910), I have called attention to a form of Leptospermum scoparium with double flowers which was discovered by Mr. E. Phillips Turner, F.R.G.S., in the Volcanic Plateau Botanical District. A second plant with double flowers was found some four years ago at Torrent Bay, Nelson, by a lady residing at Motueka. This information I received from Messrs. Nairn and Sons, nurserymen, of Christchurch. A third plant with double flowers must now be recorded. This was found recently by Mr. Leonard H. Wilson on his property at Port Levy, Banks Peninsula. I am indebted to Mr. J. Young, Curator of the Christ- church Botanical Gardens, for calling my attention to this interesting plant and for supplying the fine photograph (see Plate IX) of the wild plant in its original habitat, the photograph being taken by his son,, Mr. James E. Young. Cuttings from the Port Levy plant were struck by Mr. Young, so that there is now a vigorous specimen in the collection of New Zealand plants in the Christchurch Botanical Gardens. Since the doubling of flowers is essentially a teratological phenomenon, one cannot look on such a race, capable only of being reproduced artificially from cuttings or layers, as equivalent to a taxonomic variety. I would propose for it the garden name of " Leonard Wilson," the plant to be known therefore as Leptospermum scoparium Leonard Wilson. 40. Myrtus Ralphii Hook. f. This species was founded by J. D. Hooker on specimens collected by Dr. Ralph near the City of Wellington in the very early days of the province, and on the east coast of the North Island by Colenso, and it was first pub- lished in the Flora N ovae-Zelandiae in 1853. Later, in the Handbook of the New Zealand Flora, Hooker suggested that it might be a variety of Myrtus bullata Sol. The species was accepted by T. Kirk (*%McZe«? Cresolia Light oil 1 4,000 3 5 p.m. 6 p.m. 7.30 p.m. 9 p.m. 1 8,000 3 6.25 p.m. 7.25 p.m. 11.30 p.m. 1/16,000 3 6.30 p.m. 3 days later 4 days later 1/4,000 3 3.40 p.m. 4.20 p.m. 4.20 p.m. 1/8,000 2 3.50 p.m. . . 4.30 p.m. 6.20 p.m. 6.20 p.m. 1/4,000 *2 4.50 p.m. 4.52 p.m. 4.52 p.m. 1/8,000 6 3.15 p.m. . . 3.22 p.m. 3.55 p.m. 3.55 p.m. 1/16,000 *6 2.50 p.m. 2.52 p.m. 3 p.m. 7 p.m. 7 p.m. 1/32,000 6 2.50 p.m. 3 p.m. 7 p.m. 2 p.m. next day Recover in fresh water. One recovers in fresh water. Dead in 40 minutes. Dead in 2 hours 30 minutes. Dead in 2 minutes. Dead in 40 minutes. No observation between 3 p.m. and 7 p.m. Dead within 4 hours 10 minutes. No observation between 7 p.m. and 2.52 p.m. next dav. Dead within 24 hrs. * One of these was a pupa. Many other substances, including well-known disinfectants and plant- sprays, were used, but with no results worth publishing. Sulphates of iron and of copper, potassium ferrocyanide, and other well-known sub- stances gave, in the dilution of 1 in 4,000, negligible results. From the above table it will be seen that when there is no access of fresh water an emulsion of light oil may be used in the proportion of 1 in 32,000. The emulsion that will give this result must, of course, be one that contains nearly all the light oil that the emulsionizing agent can carry and that has no needless water. The formulae here given, chosen from a number that have been arrived at, may be relied upon : — (1.) Soft-soap .. .. .. .. .. 100 parts. Light oil . . . . . . . . . . 440 „ Water .. .. .. .. . . 100 „ Caustic soda . . . . . . . . 80 ,, It is best to add the light oil after the other substances have been heated together to a temperature of 100° C. This is a thick jelly, and may be diluted with water to liquefy it. (2.) Soft-soap . . . . . . . . 20 parts. Light oil . . . . . . . . 50 ,, A thick jelly-like soap. Where transport was not an important consideration the desired amount of water to make these emulsions liquid would usually be added when they were being made. (3.) Castor-oil . . . . . . . . 50 parts. Caustic soda (sat. solution of 98 per cent, caustic soda) . . . . . . . . 15 ,, Water . . . . . . . . . . 20 „ Light oil . . . . . . . . . . 170 „ 7* 196 Transactions. It is best first to make a soap by boiling the castor-oil and the caustic- soda solution. When an even yellow-green soap is formed the light oil may be added. Constant stirring is, of course, necessary whichever formula is used. As is well known, potash is generally more suitable than soda, but its greater cost makes it unsuitable for this purpose. Owing to a shortage of potash, soft-soap is becoming costly, and therefore other emulsionizing agents are being experimented with. Up to the present good results have been got with resin, neatsfoot-oil and whale-oil. The last-named is the cheapest, and will be used for work in military camps. Unfortunately, it is sometimes difficult to saponify it by the mean': always available. The castor-oil emulsion referred to above is a clear liquid emulsion, and keeps well. Art. XX. — On the Age of the Waikouaiti Sandstone, Otago, New Zealand. By J. Allan Thomson, M.A., D.Sc, F.G.S., Director of the Dominion Museum, Wellington, New Zealand. [Received by Editors, 31st December, 1917 ; issued separately, 10th June, 1918.] Although contradictory opinions were held by Hutton and Haast on the one hand, and Cox, McKay, and Hector on the other, as to the relative age and relationships of the Notocene rocks of the north and south sides of the Shag River, all these geologists were in agreement in correlating the Wai- kouaiti sandstone on the one hand with the Caversham sandstone, and on the other with the Ototara limestone. Both these correlations were accepted also by Park (1910) ; but it is necessary to remember that at that time he placed the Ototara stone as the uppermost member of the Oamaruian. Marshall, in 1906, did not attempt a more detailed correlation than that the Caversham sandstone belonged to the Oamaru system, but in 1916 he referred to the foraminiferal limestone at Sandymount, which he had previously correlated with the Caversham sandstone, as a repre- sentative of the younger limestone of New Zealand— i.e., Ototaran. Thus practically all geologists who have written on the subject have agreed that the Caversham sandstone and Waikouaiti sandstone are the same horizon and are Ototaran. The rightness or wrongness of this conclusion has more than a merely local interest, for on it hang two other questions of a more general nature. First, the age of the Dunedin volcanic series can only be limited as regard- ing its commencement by reference to the Caversham sandstone — until a detailed palaeobotanical investigation of the intervening Fraser's Gully plant-beds is available. Secondly, the Miocene age of the Oamaruian is based very largely upon Chapman's conclusions regarding the Foraminifera collected by Park from the clays underlying the Waikouaiti sandstone, and if the latter is Ototaran the clays are lower Ototaran, or more probably Waiarekan, and the Middle, or more probably Lower Oamaruian, is Miocene. Opinions to the contrary, however, have recently been independently ex- pressed by Marshall and myself (1917). Discussing the Hampden beds, I stated that " the percentage of Recent species in the Waiarekan is not inconsistent with an older age than Miocene for this stage," while Marshall concluded that " these Onekakara [i.e., Hampden] beds seem to be more rightly classed with the Eocene than with any other European system." J. A. Thomson. — Age of the Waikouaiti Sandstone. 197 Obviously, then, if Chapman's correlation of the clays of Waikouaiti with the Miocene is admitted, either (a) the lower Ototaran or Waiarekan is Miocene, and the opinions stated by Marshall and myself err in ascribing too great an age to the Waiarekan, or (b) the Waikouaiti sandstone is not Ototaran. During a visit to Waikouaiti at Easter, 1917, in company with Pro- fessors J. Park and W. N. Benson, of Otago University, I collected from the Waikouaiti sandstone at the North Head a number of brachiopods, of which seventeen were referable to Pachymagas abnormis Thomson, while the remaining three belonged to a small species of Pachymagas with meso- thyrid foramen, probably nearly related to the more orbicular forms of P. parli which occur in the Hutchinsonian of All Day Bay. Pachymagas abnormis was one of the species which I adduced in 1917 as evidence of the Upper Oamaruian age of the beds in the Takaka Valley, and subsequent discoveries have not invalidated its usefulness in this respect. 1 have since collected it in the uppermost bed of the Mount Brown limestone at the foot of the dip slope of the cuesta opposite Weka Pass — i.e., at a slightly higher horizon than the holotype, but still probably Hutchinsonian — and a single specimen in the Hutchinsonian greensands of All Day Bay. It occurs abundantly in the Awamoan mudstones of All Day Bay, and thus ranges in the Oamaru district from Hutchinsonian to Awamoan, but has not been found in the Ototaran. Now, a larger number of species are known from the Ototaran of the Oamaru district than from any other stage in any locality in New Zealand, so we are quite justified on the present evidence in considering P. abnormis a purely Upper Oamaruian species. Mr. S. S. Buckman, of Thame, England, has suggested in correspondence that Pachymagas abnormis should not be referred to Pachymagas, but should be made the type of a new genus on account of its beak characters, and if this course is followed it would be possible to differentiate a number of species within the somewhat variable series I have referred to P. abnormis. The specimens from the Awamoan mudstones of All Day Bay and from the Waikouaiti sandstone would, however, still have to be retained in the same species. The conclusion to be drawn from the presence of this brachiopod, then, is that the Waikouaiti sandstone is not Ototaran (i.e., Middle Oamaruian), but Upper Oamaruian, and it may well be Awamoan, and the underlying clays Hutchinsonian. In this connection an examination of the brachio- pods from the sandstone at Seacliff, and from the Caversham sandstone and the greensands underlying the latter rock at the back of Flagstaff, would be of considerable interest, and I should be glad to receive specimens from these localities. List of Papers cited. Marshall. P., 1906. The Geology of Dunedin (New Zealand), Quart. Journ. Geol. Soc, vol. 62, pp. 381-424 (ref. to pp. 389-90). 1916. The Younger Limestones of New Zealand, Trans. N.Z. Inst, vol. 48, pp. 87-99 (ref. to p. 93). 1917. Fossils and Age of the Hampden (Onekakara) Beds, Trans. N.Z. Inst., vol. 49, pp. 463-66 (ref. to p. 465). Park, J., 1904. On the Geology of North Head, Waikouaiti, and its Relation to the Geological History of New Zealand, Trans. N.Z. Inst., vol. 36, pp. 418-30. 1910. The Geology of New Zealand, Christchurch (ref. to p. 139). Thomson, J. A., 1917. Diastrophic and other Considerations in Classification and Correlation, and the Existence of Minor Diastrophic Districts in the Notocene, Trans. N.Z. Inst., vol. 49, pp. 397-413 (ref. to pp. 409-10). 198 Transactions. Art. XXI. — On the Distribution of Senecio saxifragoides Hook. /.' and its Relation to Senecio lagop.us Raoul. By Professor A. Wall, M.A. Communicated by R. Speight, M.Sc. [Read before the Philosophical Institute of Canterbury, 5th December, 1917 ; received by Editors, 31st December, 1917 ; issued separately. 10th June, 1918.] Plates XI-XIII. 1. Introduction. (a.) General. The problem to be attacked in this paper is suggested in the following passage from L. Cockayne (" Notes on the Plant Covering of Kennedy's Bush and other Scenic Reserves of the Port Hills," Report on Scenery Preservation, Parliamentary Paper C.~6, 1915) concerning S. saxifragoides : " It also is a most striking plant. Now, an almost identical species, named Senecio lagopus, also occurs on the main mass of Banks Peninsula, which differs from S. saxifragoides merely in the possession of numerous bristles on the leaf, whereas in the latter such are absent. Yet, so far as is known, S. lagopus does not occur on the Port Hills, nor S. saxifragoides on Banks Peninsula proper. If this is truly a fact, the distribution of these two species, each equally well suited to the rock-conditions of the area, is one of the most remarkable cases of plant-distribution in the world." The same authority, in his description of his new species, Senecio south- landicus {Trans. N.Z. Inst., vol. 47, p. 118, 1915), further says, " The species is, indeed, far more distinct from S. bellidioides and S. lagopus than are these from one another. The classification of the whole series, includ- ing those already mentioned, together with S. saxifragoides Hook. f. and S. Haastii Hook, f., is in a most unsatisfactory position. Specimens are constantly coming to me from various correspondents which it is impossible to place with any degree of satisfaction. There are undoubtedly a number of well-marked forms, which demand, at the least, varietal names. Even one fixed character may serve quite well as a specific mark. This is illus- trated in the case of S. saxifragoides and S. lagopus (the type from Akaroa), where the presence of numerous bristles, or their absence, on the upper surface of the leaf is the sole distinguishing character, so that, so far as large plants of the two are concerned, if this character were not present no one could consider them in any degree different." In this paper attention has been directed to these two species solely as they occur on Banks Peninsula. Banks Peninsula is situated in lat. 43° 32' S. and long. 175° 30' E., and forms a rough elliptical salient on the east coast of the South Island of New Zealand. Its diameter in a N.W.-S.E. direction is about twenty-five miles, and its breadth at right angles thereto about eighteen miles. Some forty miles to the westward stretches the main chain of the Southern Alps, from which the peninsula is separated by the gently inclined expanse of the Canterbury Plains, so that it is almost as completely isolated as regards the distribution of subalpine vegetation as if it had been separated from the mountain region by the sea. The oldest rocks within its limits consist of Trias-Jura sedimentaries overlain in places by a thin veneer of Cretaceous rhyolites, but the main Trans. N.Z. Inst., Vol. L. Plate XI. * W:*- ?: TO giAMii^ pE/Hi^uibH ^- v*?v %?'** Photographic reproduction of relief map of Banks Peninsula, from original in Canterbury Museum by S. C. Farr. Face p. 198. \ Wall. — Distribution of Senecio saxifragoides Hook. f. 199 mass of the peninsula was built up in mid-Tertiary times by flows of basalt and fragmentary material of similar lithological character, poured out from two vents situated somewhere near the centres of Akaroa and Lyttelton Harbours. A third focus of activity lay near Mount Herbert (3,012 ft.), but it was of less importance, although it was responsible for the formation of the highest peak in the area. The high cones thus formed were subject to paroxysmal explosions of moderate intensity, and their surface was modi- fied by the establishment on their outer slopes of a well-developed system of radiating valleys. Volcanic action ceased in all probability long before SMt Pleasant Sugar Loaf o LYTTELTON Cass Peak o s •. p Cooper's Knob o 5- 0 ^ M Castle Rock Ml. Herbert ' , Mt. Sinclair • L .°.l ° ° ° o c Mt Filigerald ° » Rocky Peak ° Map of Banks Peninsula and Port Hills, showing distribution of the two speciea of Senecio. L, Senecio lagopus ; S, Senecio saxifragoides; A, rhyolite escarpment where S. lagopus occurs ; B, rhyolite escarpment where neither species occurs. the end of the Tertiary era. After the stream-system had reached a mature stage the land sank, and the sea entered the floors of the enlarged craters and extended a considerable distance up the lower reaches of the valleys, and these now form marked indentations of the coast-line. Owing to the prolonged weathering the land is now covered with a rich and fertile soil, and steep rock-faces occur only on the coast and at higher levels, where the more resistant basalts form at times precipitous cliffs — the characteristic habitat of the senecios under consideration. The following are the most important geological considerations affect- ing the distribution and ecological conditions of plants established in the locality : — (1.) The isolation of the region from neighbouring mountain areas since it was first formed. 200 Transactions. (2.) The uniformity of the lavas which form the majority of rocks in the area. No anomalies of distribution can be interpreted in the light of lithological differences in these rocks. (3.) As a result of prolonged denudation the crater-ring of the Lyttelton volcano has been broken down at its south-western side and a sector completely removed, so that a stretch of comparatively low country, nowhere over 875 ft. in height, and consisting of exposed rhyolites and sedimentaries, separates the northern part of the crater-ring from the other part of the peninsula. This northern part forms the low range usually called the "' Port Hills," and is referred to throughout this paper, as the habitat of Senecio saxifragoides, by this name. For a fuller account of the geological features of this area see J. von Haast, Geology of Canterbury and Westland, 1879, and R. Speight, " The Geology of Banks Peninsula" (Trans. N.Z. Inst., vol. 49, pp. 365-92, 1917). (b.) Historical. Senecio saxifragoides was first described by Hooker in 1853 (Flora Novae- Zelandiae, vol. 1, p. 144), and in the Handbook its discovery is accredited to Lyall (Handbook, p. 159). Hooker, Kirk (Students' Flora, p. 339), and Cheeseman (Manual, p. 372) agree in describing S. saxifragoides as distinguished from S. lagopus only in respect of the leaf, which is described as " clothed with shining silky and woolly hair " (Hooker), " silky or villous " (Kirk), " silky or villous " (Cheeseman), upon the upper surface only, and wanting the stout bristle which characterizes S. lagopus and S. bellidioides. Kirk says, " The leaves are often glabrous or glabrate on the upper surface, but never bristly as in S. lagopus." Cheeseman says, " A handsome species, separated from large states of S. lagopus, some of which approach it very closely, by the much stouter habit, more copious villous hairs, and larger thicker leaves, which are silky above and never show the stout bristly hairs so charac- teristic of S. lagopus and S. bellidioides." All agree that these three species, *S. lagopus, S. bellidioides, and S. saxifragoides, are very closely allied. Hooker (Handbook) says, ' This [S. lagopus] and the two following [i.e., S. bellidioides and IS. saxifragoides], though most dissimilar in their usual states, appear to me to be united by intermediate forms," and (Flora Novae-Zelandiae), " This and the two following are closely allied and very singular species." The distribution of S. saxifragoides is given by Hooker as ' Port Cooper " ; by Kirk as " Port Lyttelton, Banks Peninsula " ; and by Cheese- man as " Port Lyttelton and other localities on Banks Peninsula." All agree in describing the leaf of S. saxifragoides as broader or more nearly orbicular than that of S. lagopus ; but they do not quite agree as to the relative size. Hooker makes the leaf of S. lagopus 2 in. to 4 in. long (!) ; that of aS. saxifragoides 3 in. to 5 in. long. Kirk makes the leaf of S. lagopus 1 in. to 8 in. long (excluding the petiole), and that of *S. saxi- fragoides 3 in. to 6 in. long. Cheeseman makes the blade of *S. lagopus 1 in. to 5 in. long, and that of S. saxifragoides 3 in. to 6 in. long. Raoul's description of S. lagopus (Choix, p. 21) gives the leaf about 1 decimetre (4 in.) long and from 7 to 9 centimetres (3-3J in.) broad. Hooker's and Raoul's descriptions would seem to have been based upon comparatively small specimens of both species. Wall. — Distribution of Senecio saxifragoides Hook. f. 201 The distribution of S: lagopus is given by all authorities as from the Ruahine Mountains to South Canterbury. The original description of S. lagopus by Raoul, and his plate (Choix, pi. 17), must here be referred to, as of the greatest importance in the study of the two species. In describing the petiole of S. lagopus, Raoul says, " Petioli . . . canaliculati in vaginam semiamplexicaulem dense lana- tam dilatati " ; and in describing the leaf he says, " Folia . . . pilis rigidis grossis, spinescentibus praesertim ad margines inspersa." His plate shows a plant with four large and several small leaves. Of the four large leaves three are glabrate (as the old leaves of both S. lagopus and S. saxi- fragoides always are) : the fourth bears the characteristic " bristles " very thickly close to the margin all round the leaf, or nearly so, and near the apex ; less thickly upon the upper third of the leaf or thereabout ; the lower part of the leaf bears the hairs only, very thickly distributed. The hairs and bristles occur together over some portions of the leaf, about the middle and towards the apex, but at the apex itself and in its immediate neighbourhood the bristles alone occur. The dual occurrence of hair and bristle* on the same leaf, which no subsequent authority describes at all, will appear to be of great importance to this inquiry ; and it may be added that my descriptions of the variant forms of S. saxifragoides given below were fully made before I had seen Raoul's plate. The species are further thus referred to by Laing and Blackwell (Plants of New Zealand, pp. 437-38, 1906) : ' The handsome S. saxifragoides, sup posed by Kirk to be confined to Banks Peninsula, is undoubtedly the typical S. lagopus of Raoul. It still produces its large-leaved rosettes on the southern faces of cliffs, where Raoul found it, near Akaroa. It is also plentiful behind Lyttelton, often growing in altogether inaccessible localities, and it is the only Senecio which haunts these situations on the Peninsula." 2. Special ^Characters of the Two Species [under Consideration. 1. All round the margin of the leaf of S. lagopus, S. saxifragoides, and S. belUdioides occur at very regular intervals — i.e., at the ends of the veins — rounded glandular protuberances of a very dark red or purple colour. Microscopical examination shows these to be typical hydathodes. 2. The petiole of the leaf of S. lagopus bears quantities of dark-red or purple bristles, generally spotted or pied with white ; these are continued up the back of the midrib nearly to the apex of the leaf, and are also present along the margin all round the leaf. 3. S. saxifragoides also shows this purple or pied bristle upon the petiole and the back of the midrib exactly as in S. lagopus, and also bears this bristle all round the margin of the leaf, making a continuous fringe. The young leaves of S. saxifragoides have yellow marginal bristles, which change gradually into purple and continue to deepen in colour up to maturity. The yellow bristle, however, is usually present together with the purple, the yellow being upon the upper surface of the leaf just within the margin, the purple being upon the margin itself ; but they are sometimes more or less mixed together. 4. Forms of Senecio lagopus and Senecio saxifragoides which grow in situations shaded by other vegetation, as among long tussock-grass, or on * The term " bristle " is kept throughout, as that employed by previous authorities though the organ is really a glandular hair. 202 Transactions. the edge of forest, or beneath large plants of Linum monogynum, show a complete or almost complete absence of the purple colouring-matter in the glandular hairs, and also tend to be larger, to have a much longer petiole than usual, and to be less thickly covered with silky hairs or bristles (as the case may be) than the usual form. 5. Though the plant of S. saxifragoides is probably on the average a little larger than that of S. lagopus, the difference is not great. Kirk's measurements do not agree with the others. A leaf of S. lagopus 8 in. long without the petiole would be most exceptional, but leaves 6 in. long with a petiole of from 3 in. to 4 in. are common — e.g., on Mount Herbert — and S. saxifragoides can hardly ever be much larger than this, though its leaves are generally broader and more substantial. I have a very strong impres- sion, which I hope to verify by future observation, that the plants of S. lagopus in the neighbourhood of Akaroa Harbour are in general distinctly smaller than those of the Mount Sinclair to Mount Herbert area. This would explain the small measurements of Raoul's type. Some of the large individuals of the Mount Herbert area, indeed, almost seem to be inter- mediate states such as Hooker speaks of. The largest leaf of S. lagopus measured by me shows the following dimensions : Length of blade, 6 in. ; length of petiole, 3 in. ; breadth of blade, 4 in. This plant grew on the south-western peak of Mount Herbert, and was exceptionally large. Its measurements equal those of S. saxifragoides in any authority and exceed most of them. A most exceptionally large plant of S. saxifragoides, how- ever, gave the following 'measurements : Length of blade, 1\ in. ; length of petiole, 4J in. ; breadth of blade, 6f in. This is much above the average of the species, the plant being shaded by plants of Linum monogynum and tussock-grass. 6. Thus the leaf of typical S. lagopus is found to bear six different types of structure — (a) The thick brownish " wool " of the rootstock, which covers the base of the petiole and seems to pass gradually into (b) long white silky hairs, which clothe the petiole and are continued up into the sinus and on to the lower portion of the leaf ; (c) the characteristic stout bristle Which occurs, as described below, on the margin and upon the upper part of the blade especially ; (d) the dark-red or purple bristle which is thickly inter- mixed with the white hairs upon the petiole, from the point where the brownish " wool " passes into white hairs up to the apex, or nearly, on the back of the midrib ; (e) the glandular marginal purple protuberances ; (/) the white tomentum upon the back of the leaf. 7. Many plants of S. lagopus bear the silky hairs as well as the charac- teristic stout bristles. The silky hairs usually occur very thickly on the petiole and at the base of the leaf and in the immediate vicinity of the midrib ; less thickly, if at all, on the rest of the leaf, as depicted in Raoul's plate. 8. Many plants of S. saxifragoides bear the stout bristles which have been hitherto considered to be characteristic of S. lagopus and S. belli- dioides. The bristles occur in S. saxifragoides under these conditions :— (a.) They occur near the apex of the leaf upon the upper surface of about one-fourth or one-third of the whole — not near the base, and but rarely on the lower half of the leaf at all (as in Raoul's plate of S. lagopus), though specimens have been observed with the bristles fairly evenly distributed over the whole surface. (See Plate XII.) (b.) They occur regularly and as a permanent character all round the margin exactly as in S. lagopus and S. bellidioides. Trans. X.Z. Inst., Vol. L. Plate XII. Youno- plant of Senecio saxifragoides, showing bristles, from Mount Pleasant. Port Hills. face p. 202 Trans. X.Z. Inst., Vol. L. Plate XIII. £ _2 to tn 02 o o 02 a - o a o T3 m\ o g J3 is GO O o Another Alternative Explanation. An account of the geological history of the coastal lowland which diverges considerably from that assumed in the ex- planation of the physiography here adopted was given by Adkin,* whose account deals in particular with that part of the lowland adjoining the Ohau Kiver. Adkin's classification of various stages in his concept of the history of the lowland as Early Pleistocene, Middle Pleistocene, Later Pleistocene (First, Second, and Third stages), and Recent must be discarded, as he had no means of correlation with deposits of Pleistocene age elsewhere ; and for the present purpose the stages " Early Pleis- tocene ': to ' Recent " may be renamed stages 1 to 6. According to his interpretation, at stage 1 the Ohau River built a great fan over hypo- thetical undissected uplifted Pliocene forma- tions with a plane surface, the latter being vaguely ;t inferred from the configuration and character of the superimposed fluviatile deposit." Large parts of the surface of the fan formed at this time are regarded as surviving to the present day, though buried by a marine deposit and re-exposed by erosion in the intermediate historical stages. Stage 2 was a period of complete sub- mergence of the lowland beneath the sea. This was followed by a period of still-stand, succeeded by uplift continuing to the present day. During the submergence at stage 2a" raised-beach formation " was deposited, consisting of beach sands spread over the whole area of the lowland partly during the advance of the sea and partly during its retreat. This " raised-beach for- mation" comprises the partially consolidated sands of the older lowland. Adkin states that its present level surface is not the original one, as it has been lowered by erosion. It is not clear, however, to what base-level he ascribes the planation, or at what stage of the history it occurred. Dis- section of the surface by small streams is men- tioned in the description of an illustration. * G. L. Adkin, The Post-tertiary Geological History of the Ohau River and of the Adjacent Coastal Plain, Hoiowhenua County. North Island, Trans. N.Z. Inst., vol. 43, pp. 496-520, 1911. 220 Transactions. The remaining stages are marked by changes in the courses of the Ohau and other streams over the Ohau fan, for the explanation of which Ferrel's law is invoked, though it is much more probable that such changes as have taken place in stream-courses have resulted from spilling over as a normal accompaniment of aggradation. At the same time the shore-line advanced steadily seaward. It is not clear whether this is regarded as entirely the result of an inferred movement of uplift, but this is probably what the author had in mind, as he speaks of the whole lowland as a coastal plain. The new land formed thus was progressively covered with sand-dunes, which impounded lakes. The account is somewhat difficult to follow, but the foregoing is a fair summary. Adkin regards the gravel plains, such as the Ohau fan, as the oldest, instead of placing them among the youngest elements of the lowland physiography, as is done in the explanation now offered ; and his conclusion that any portions of the existing fan-surfaces or gravel plains were in existence prior to the deposition of the sands of the older lowland is an extremely doubtful one, whatever the correct explanation of the mode of accumulation of those sands may be. It must be added that Adkin's work is obviouslv based on a large amount of careful field-work ; and his mapping in the Ohau River district (Horowhenua) is extremely useful. Subdivisions of the Lowland. The Otahi Series. The oldest physiographic element in the lowland is, then, the dissected peneplain of soft sandstone corresponding to the " older dune-sand areas " of the theoretical discussion previously given, and comprising the " raised- beach formation " of Adkin. To the lithological formation of sandstone thus indicated the name Otaki series may be applied as a local formation- name, as it is well developed just north of the Otaki River and town. Topography on the Otaki Series. — The topography is that described in the theoretical section as developed on the " older dune-sand areas," and shown diagrammatically in fig. 2, F (see also Plate XV, fig. 2). I agree with Adkin* that the gently undulating tops of the broad benches of this forma- tion are parts of a surface of erosion and not of deposition. In some parts of the district a considerable area of the surface of the Otaki series consists of broad terrace-remnants of valley-floors at intermediate levels developed generally by very small streams which now make their way along the flat, swampy floors of inner valleys. A striking characteristic of the small dissecting streams arising within this formation is the steepness of their valley-sides, which remains practically constant as the width of the floor increases, and the same slope continues around the valley-heads. To their very heads the valleys are box-shaped rather than V-shaped. The slopes separating the broad terraces at intermediate levels were evidently once exactly similar to those of the inner trenches, though they have become somewhat dissected and broken down since the streams were revived and undercutting of these slopes ceased. Where the terraces have been developed by gravel-bearing streams heading in the old land they are gravel-covered. Distribution of the Otaki Series. — Between the southern end of the coastal lowland and the Manawatu River the Otaki series, with its charac- * Loc. cit., p. 509. Cotton. — Geomorphology of South-western Wellington. 221 teristic topography, covers an area of perhaps sixty square miles, of which about half consists of nearly flat summits. One considerable area occurs between the Otaki and Ohau Kivers ; an island " of it, surrounded by gravel plains evidently parts of the Ohau fan spread by distributaries of that river, occurs at Weraroa, where the Central Development Farm of the Department of Agriculture is situated partly on this formation and partly on the fan ; and there is then a nearly continuous bench, broken only by some gravel-covered valley-floors, extending north-eastward for twenty miles. Lithology and Structure of the Otaki Series. — The prevailing material in the Otaki series is grey sand similar in mineral composition to that of the present beach and the associated dunes. In addition to quartz, the sand contains a considerable proportion of feldspathic, ferromagnesian, and iron- oxide grains. The mineral grains, including those of quartz, though not completely rounded, have their angles smoothed off, and they thus contrast very strongly with the sharp, angular grains of the present beach. This suggests aeolian accumulation. All the samples examined are somewhat weathered, however, and the rounding of grains may be ascribed in part to weathering. The more or less coherent sandstone formed of this material weathers at the surface to a residual sandy clay, usually containing scattered spheroidal masses of the sandstone. The permeability seems not to be great, for the water-table is generally close to the surface. Much water seeps out along the bases of even low scarps, and necessitates draining. In the few sections where bedding has been noted the beds are inclined at about 35°. It is quite clearly cross-bedding on a large scale, and again suggests subaerial accumulation. Cross-bedding and also ripple-mark are noted by Adkin.* A horizontal pseudo-stratification, due, apparently, to deposition of iron, is also generally present. Though less prominent, it seems to resemble that noted by Berkeyj* in the aeolian San Juan formation of Porto Rico. The non-discovery of fossils, J though a negative character, points also to the possibility of subaerial accumulation of the sand of the Otaki series. Clay lenses and bleached soil-beds, which are interbedded with the sand- stone, accumulated, no doubt, in lakes and swampy areas impounded among dunes. The clay-bed between upper and lower sands noted by Adkin, § which he ascribes to marine deposition at a period of maximum depression, is perhaps one of these. In one section near Shannon layers of small pebbles occur interbedded with the sand. Here is probably the course of one of the smaller streams from the old land, or perhaps the margin of one of the larger fans. If gravel fans and dune sands accumulated side by side, as is assumed in the theoretical section, there must be a considerable amount of intermixture of material along the transition lines where gravel passes laterally into sand. Along these lines, indeed, a complex interfingering of gravel and sand beds may be expected. The Fans or Gravel Plains. Throughout the length of the lowland there are numerous gravel fans, both great and small. The largest are those of the Otaki and Ohau Rivers, * Loc. cit., p. 507. t C. P. Berkey, Geological Reconnoissance of Porto Rico, Ann. N.Y. Acad. Sci., vol. 26, pp. 1-70 (see p. 50), 1915. J G. L. Adkin, loc. cit., pp. 497, 507. § Loc. cit., p. 507. 222 Transactions. which have a combined area of about forty square miles. Some parts of their surfaces are thickly covered with small boulders or coarse gravel ; others have a gravelly soil ; while others, again, have a superficial layer of silt overlying gravel. Most of the fans are trenched and terraced to a small extent. The surfaces of the fans and of terraces cut in them are very similar to one another, as are also gravel-covered terraces within the border of the old land. All these may be classed as gravel plains. The gravel- bearing streams are at present aggrading as though to refill the trenches in the fans. The actual stream-beds are,' therefore, areas of bare gravel over which the streams flow in changing, braided channels. As previously mentioned, the upper surface of the Otaki formation passes in some places into that of a fan without any abrupt break of slope. The Delta of the Manawatu. More or less analogous with the fans of the. southern part of the lowland is the delta of the Manawatu River ; but this is one, perhaps the chief, of the sand-supplying rivers. Its delta is composed mainly of fine material, and its gradient is very gentle as compared with that of the gravel fans. The Manawatu delta forms a plain of wide extent lying at present almost entirely on the north side of the river, and continued up-stream by a wide flood-plain, below which the river is now slightly entrenched, and above which there are broad terraces on the northern side. The seaward margin of the delta is covered with dunes, some belts of which extend inland many miles. The Manawatu River at present bends to the south-west after emerging from its gorge across the old land, and at a not very distant date it swung still farther to the south. The toe of the bench formed by the Otaki series is here cut back to a line of cliffs by the action of the river, and at the base of these a considerable area of ill-drained flood-plain, now abandoned by the river owing to its slight entrenchment, forms the great Makurerua Swamp (see fig. 1). The whole of the delta plain was formerly swampy, but a great part has been artificially drained. The Modern Dunes. The modern dunes are built of grey sand similar to that forming the sandstone of the Otaki series. All except a narrow belt close to the sea are fixed by vegetation, but beneath the superficial layer of humus the sand is still quite loose. The belt of dunes has a width of from three to six miles, and their average height is 170 ft. Adkin notes that their general arrangement is in ridges at right angles to the coast-line.* The shore-line of the dune-covered foreland advances as a broad cusp towards Kapiti Island (a high island of old rocks some four miles from the mainland). This is evidently an early stage of island-tying. Lakes and Swamps. Several lakes and many small ponds and swamps formed by the silting- up of ponds lie between the modern dunes and the margin of the other physiographic elements of the lowland, and there are many swampy areas among the modern dunes. The valley-floors in the Otaki formation are practically all swampy, as a result either of normal aggradation with fine silt or of ponding by sand-dunes followed by accumulation of silt. The largest swamp in the district — the Makurerua Swamp — has been referred to above. * G. L. Adkin, loc. cit., pp. 514-15. Chambers. — New Zealand Ironsands. 223 Aet. XXIV. — New Zealand Ironsands : an Historical Account of an Attempt to Smelt Ironsands at Onehunga in 1883. By J. M. Chambers. Communicated by Mr. Evan Parry. [Read before the Technological Section of the Wellington Philosophical Society, 13th Jane, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 17th June, 191s. | It is extremely difficult after a lapse of nearly thirty-five years to obtain a complete history of this undertaking, as the directors of the New Zealand Iron and Steel Company (Limited) are all dead — in fact, almost everybody who had any connection with it. Its records have been lost or destroyed, and the only data I have have been obtained from a private letter-book and a few odd documents which I found amongst my father's papers. In 1866 Mr. John Chambers arrived in New Zealand, and soon after- wards saw the ironsand on the beaches of Taranaki. He was much im- pressed with it as a valuable asset, if the material could be converted into marketable iron. From some early settlers he learnt that 100 tons of sand had been sent to Staffordshire, where it was manufactured into iron by David Hipkins, who wrote that he smelted and puddled the sand into bars, sheets, hoops, boiler-plates, and fencing-rods, afterwards making it into horse-shoes, chain, &c. All were tested and pronounced equal to any of the Staffordshire irons ; but owing to cost of manipulation he would not recommend his principals to obtain further supplies or establish a works in New Zealand. Later, in 1876, Mr. Chambers took a parcel of ironsand to England and the United States. He interviewed many ironmasters, but could get none sufficiently interested to experiment seriously with the samples, excepting in laboratories, where a few pounds of iron and steel were produced in crucibles. In 1886 I attended the Indian and Colonial Exhibition, where there were exhibited a parcel of sand and some iron manufactured by the above com- pany. While in London I was introduced to W. T. Jeans, Price Williams, and Sir Henry Bessemer, all of whom were interested in the sands of New Zealand and Canada. Arrangements were made with Sir Henry Bessemer to carry out a series of experiments. His report was unsatisfactory, for, although he claimed that the best-quality iron and steel could be produced, it would require a great deal of research work, and he was too old to go on with it. Just before Sir William Siemens died, in 1883, he stated that his atten- tion had been called to the ironsand in New Zealand and Canada, contain- ing about 50 per cent, of metallic iron, and he demonstrated with a patent rotating furnace that he could manufacture iron from the ironsand of Canada, producing iron balls in four hours, which were then treated in the open-hearth furnace and converted into mild steel. At that time his process was tried in Pittsburgh, but unfortunately it did not prove a commercial success, on account of cost. Mr. John Chambers visited the Philadelphia Exhibition in 1876, and there tried to induce men in the iron and steel trade to test the ironsand ; but nothing could be arranged, as all the ironmasters of America were fully occupied in building additional works to handle the trade which they could 224 Transactions. easily get in America for all the iron that could be produced from ordinary iron-ore at a cheap rate. But before leaving New York Mr. Chambers heard that Mr. Joel Wilson, of Dover, New Jersey, had in 1873 patented a furnace which he claimed would treat ironsand and convert it directly into wrought iron ; but everything was in an embryo state, and it was arranged for an agent to watch the work of Mr. Wilson, who claimed in 1882 to be able to manufacture successfully from sand. Mr. Guy H. Gardner, of New York, obtained an option on the New Zealand patents, purchasing them jointly with Mr. Chambers ; and so sanguine was the inventor that he agreed to send out his best man, Mr. W. H. Jones, to demonstrate the working of his patent in New Zealand. A full-size furnace was erected in 1882 to manufacture 3 tons of iron per day. The furnace was built from a drawing accompanying patent speci- fications granted to R. L. Malcolm (J. Wilson)* and G. H. Gardner,"}" except that the reducing-furnace contained eight retorts, instead of sixteen as shown on the drawing accompanying Malcolm's patent. The drawing of the furnace as built has been reconstructed and shown in the figure accom- panying this paper. It consisted of a deoxidizer, A, and of an ordinary reverberatory or open-hearth furnace, about 17 ft. long, divided into three compartments — B, the balling-furnace ; C, the puddling-furnace ; D, the fire- grate. The coal used for firing on the ordinary furnace-bars was from Westport and Newcastle. The hot gases from the furnace played direct on the floor of the puddling-furnace C, passed on to the balling-furnace B, then passed through the roof into a central flue F, about 2 ft. in diameter, and were carried up the full length of the deoxidizer, a height of 21 ft. ; the gases struck the crown at the top of the furnace, and passed in a downward direction between the retorts R, there being radial spaces F between the retorts for the gases to pass through ; on reaching the bottom they were deflected so as to pass upwards (F) on the periphery or outside of the surface of retorts, and between that and a firebrick lining against the shell of furnace. On the gases reaching somewhere near the top they passed out into an annular flue and by way of an iron chimney into the atmosphere. The deoxidizer held 10 tons of carbon and ironsand. After the silica had been extracted by a magnetic separator it was thoroughly mixed with 20 per cent, to 25 per cent, of coal or charcoal, Taupiri coal being used. The material was hoisted to a platform above the deoxidizer, from which each retort was filled from filling-boxes. It required twenty hours to deoxidize or carbonize the iron by driving out the oxygen. The sand was red-hot, but not so sticky that it would not run through the chutes leading to the balling-furnace, which were controlled by heavy gate-valves. The deoxidized sand dropped on to the floor of the balling-furnace, where it lay for some thirty minutes, there being a door at the side of the furnace to permit the puddlers to test the condition of the material before balling it. It would work up exactly as cream works into butter, having very much the same appearance. On a ball of about 18 in. diameter being made it was rolled or passed over to the puddling-furnace C, when it was again attacked by a fresh set of puddlers, who vigorously worked it up *" Malcolm, R. L. — 8th January, 1883 — Improvements in furnaces for reducing iron-ores," N.Z. Pat. Reg. No. 762. t" Gardner, G. H. — 23rd April, 1883 — Improvements in furnaces for the manu- facture of bar iron and blooms," N.Z. Pat. Reg. No. 818. Chambers. — New Zealand Ironsands. 225 until it was ready for the squeezer ; or, in the case of the first trials, the ball was placed on the anvil of a steam-hammer and gently squeezed into a square form, after which it could be hammered with the full force of the hammer and drawn into the shape of a billet or bloom. The cost of the first furnace was £500. It was completed early in February, 1883, and on the 27th the first iron by the new process was Design of Ftrnace. A, deoxidizer : B. balling-furnace ; C, puddling- furnace ; 1), fire-grate; F. flues; R, retorts. made into billets, and it was shown that the quality exceeded all expecta- tions. On the 5th March George Fraser and Sons, Auckland, made three bars, 8 ft. long, 2 in. square, of perfect quality. The furnace, under the charge of W. H. Jones, was kept working for about ten days, and at that time good blooms were produced, which were worked up into bar^ and thoroughly tested by several leading blacksmiths in Auckland, Mr. George 8— Trans. 226 Transaction*. Leahy making a large double pair of ornamental gates of beautiful design to demonstrate the quality of the iron, which was equal to Netherton Crown. After a stoppage for some necessary repairs the fires were lit for a second time. The best results obtained from one charge in the deoxidizer was the manufacture of 6,751 lb. of iron from 14,625 lb. of sand ; the slag or cinder amounted to 7,215 lb., the loss of cinder and waste in furnace being reckoned at 659 lb., resulting in 46^ per cent, of iron being produced from the sepa- rated sand. The operations were carefully watched by Messrs. James Stewart and Edmund W. Otway, of Auckland, who on the 29th March made the following report : — tc We have the honour to state that, as requested by you, we have attended at your works erected at Onehunga for the reduction of the iron- sand, for the purpose of examining in detail the whole process and obtaining data for reporting on the cost of production. We are as yet unable to make a complete report, but hasten to give you a few of the more important results, and the deductions which may fairly be drawn from them. We, hope shortly to report in a more exhaustive manner. " On Monday, the 19th instant, four retorts were filled with a mixture of ironsand and charcoal, in the proportions of one measure of sand to two of charcoal. Other four retorts were filled with a mixture of ironsand and ground Waikato coal, in the proportions of two measures of coal to three of sand, the intention being to put in 20 per cent, by weight of both char- coal and coal in proportion to the sand. The above mixtures give that percentage of coal, but more than that of charcoal, and in subsequent operations in filling up the exact ratio of 20 per cent, was adhered to. " The fires were lighted on Monday night, and on Wednesday a small charge was tried, but found not sufficiently carbonized or deoxidized- either term appears correct. Puddling was therefore deferred until Thurs- day, the 22nd, and was then commenced with the coal mixture principally. But it soon became apparent that the coal was not in sufficient proportion to carbonize the ore, and after working all day with a very poor result it was determined to discharge all the coal mixture remaining in the retorts and recharge with charcoal and ore. " On Friday work was resumed with better success, but, as coal mixture had been used to fill up the shrinkage in the retorts remaining to be worked, its presence still caused trouble, principally by the great amount of slag produced, and iron dry and difficult to work to nature, causing the blooms to be returned to the furnace once, and sometimes twice. " On Saturday the work went on very well, and if the draught of the furnace had been perfect little could have been desired in the result. " We have worked out the result in two ways : (1 ) total sand ore worked by both mixtures, against total yield of iron : (2) discarding the yield of iron on Thursday, when the iron-ore was mixed with the coal, as obviously the fairest view to take. The first result is 38 cwt. of iron from 149 cwt. of sand, equal to 25-5 per cent, (very nearly) of puddled blooms. The second view gives 33-25 cwt. from 98 cwt. of ore, equal to 34 per cent, (nearly) of puddled blooms. " From the somewhat extemporized nature of the works, we feel con- fident that the above percentage at least can be maintained by carbonizing with charcoal. And by increasing the coal mixture to an amount equiva- lent to 20 per cent, of carbon we have reason to believe a like result will be obtained. " Discarding Thursday's run, the coal used in puddling and keeping up the heat at night on Friday, Saturday, and Monday, including the coal Chambers. — New Zealand Ironsands. 227 » necessary to keep the furnace hot over Sunday, was 3-21 tons, which works out to 38-6 cwt. per ton of blooms. We feel quite safe in saying that with continuous working the conversion of the ore can be effected at under 30 cwt. of coal per ton of iron, and that all the heat and firing required by the whole process can be supplied by the waste heat from the furnace and retorts in the use of that weight of coal. This is even with the direct use of coal ; but with the most improved gas regenerative furnace not only will the amount of coal be very largely reduced, but much inferior fuel may be used. " Keeping in view all the above points, we have no hesitation in saying that the process has been shown to be profitable, but to what extent we are yet unable to say. We trust, however, that this interim report will be of service to you." It was estimated the cost of manufacture would be as follows :— Cost of 3 tons of ironsand at works, at 6s. 8d. per ton 30 cwt. coal at works . . Carbon for retorts Puddling, per ton Shingling, rolling into puddle-bars, weighing, shear- ing, piling, reheating, and rolling into 1 in. bars 0 10 0 Engine-driver's time, millwright, bricklayers, &c, and incidental expenses . . . . . . 0 10 0 £5 0 0 Add 25 per cent, for establishment charges, depre- ciation on plant . . . . . . ..150 Cost per ton . . . . ..£650 £ s. d. 1 0 0 1 10 0 0 10 0 1 0 0 When the furnace was working during April the works were visited by Mr. Pearson, of Pearson, Knowles, and Co., of Warrington, who took a great interest in the work, and said the process represented the greatest advance of the present age. At the same time they had another distin- guished visitor — Mr. Sydney Gilchrist Thomas, of London, inventor of the basic process which did so much to cheapen the cost of manufacturing steel. He declared that for the first time he had seen wrought iron made direct from ore, and it was what all ironmasters had been trying to do for a century. He was prepared and wished to enter into a contract for the purchase of 5,000 tons of blooms per annum. As a result of the visits of these two men and the favourable reports obtained from all quarters it was resolved to form a company with a capital of £200,000, made up of 40,000 £5 shares : of these, 9,103 were subscribed by the public, leaving a balance of 30,897 ; the paid-up capital being £45,515. The total expenditure was about £58,000, the plant and build- ings costing £34,329. The company proposed to order sufficient material and plant for the erection of ten deoxidizers and furnaces. A rolling plant was ordered from Messrs. Walker, Eaton, and Co., of Sheffield, who supplied an 18 in. forge- train with squeezer, pendulum shears, and engines, a 14 in. and 10 in. merchant mill, hot-saw, two shingling-hammers (each of 50 cwt.), and all necessary gear for a complete works to turn out 30 cwt. of bar iron or rolls per day. Four Lancashire boilers and four Wilson gas-producers were 228 Transactions . ordered from Tangyes Limited, to provide gas for heating furnaces, firing boilers, &c, it not being proposed to use coal in any furnace or place. The site on which the experimental furnace was erected was purchased, consisting of about 5 acres on the south-east side of the Onehunga railway- station, from which a siding was run into the works. It had a water frontage, which became valuable by a canal being cut to deep water to enable vessels of light draught to come right into the works, so that West- port or Newcastle coal could be delivered direct. It was a fine site, having many advantages, several springs providing a good supply of fresh water. It was admirably situated for cheap and economical working, for it was intended that the ironsand should be brought from the North Head of Manukau Heads, where a Government lease, of sixty-six years, was obtained for 6 j miles of beach and 1,000 acres of land, on which there were millions of tons of iron. There was good shelter and deep water at the Heads for loading, it being proved from actual experience that the sand could be raised, trucked, delivered to vessel, and conveyed to works at a cost not exceeding 6s. 8d. per ton. The average sample of ironsand obtained from the Manukau Heads would analyse as follows :— iron-oxiae Titanium Lime Magnesia Silica . . Loss 88-88 0-30 Trace 9-98 0-84 100-00 Equal to 66-36 per cent. iron. The patience of the shareholders was somewhat tried by the long wait for machinery to come from Great Britain. Contracts were let for a furnace- house to contain the forge-train, which measured 106 ft. by 100 ft. The roof of this building had a single span. There was also a similar building, 100 ft. square, for the merchant mills and reheating furnaces. Offices, laboratory, carpenters' and engineers1 workshops, foundry complete with cupola, set of furnaces for making crucible steel, storage, drying and mixing shed for coal and sand, were all got under way, and, in addition, a brick- kiln, which turned out 200,000 firebricks before the machinery arrived. The prospects were bright and every one was sanguine of success ; but on the 23rd December the company suffered a great blow by Mr. W. H. Jones quarrelling with a bricklayer, whom an hour or two afterwards lie shot in the main street of Onehunga, for which he got ten years' hard labour. No suitable man could be obtained from America, and it was thought that Mr. Edmund Otway, an old ironmaster, would fill the position, which he did for some months. He was a very capable man, but unfor- tunately he broke down and died in June, 1884. This was looked upon as a serious loss, but fortunately the position was filled by Mr. John Heskett, at one time manager of one of Bolckow Vaughan's works at Micldlesborougli, who proved to be thoroughly capable, and manfully carried on the work. He, unfortunately, had to fight against great diffi- culties through ill health, and finally broke down at a critical time, when the works were completed and ready to commence operations. On the 7th November, 1884, the first machinery arrived from England ; it was quickly erected, for by the 1st May, 1885, the fires were lit in two furnaces, when it was shown that 1 ton of bars could be made from 3 tons Chambers. — New Zealand Iron sands. 229 of 75 per cent, oxide that is, the sand as found on the beaches. The new furnaces were supplied by gas under forced draught generated by the four Wilson gas-producers, and all worked well for a few days, when it was found that the coal contained too much moisture, which destroyed the heating properties of the gases. Again and again endeavours were made to overcome this difficulty. The fires would be lit in the gas-producers, and the quality of gas for the first few hours would be perfect ; but as the furnaces became hot and just about ready for men to work the sand and deoxidizers the heat gradually fell away, or a series of explosions took place, which showed it was time to stop. This was one of the first diffi- culties met with, and one that was never overcome in spite of many experiments. By this time the shareholders were becoming impatient, for they wanted to see returns. The loss of two managers, followed by the enforced retire- ment of Mr. John Heskett, had a good deal to do with the company breaking up. Mr. James McAndrew, an ironmaster, who had been on the Clyde, accepted the position of manager, and did his best to produce iron from sand, but none of Mr. W. H. Jones's successors could produce iron of the same quality as he did. There were difficulties with the deoxidizers : air seemed to leak through or get into the retorts, resulting in a portion of the sand not being deoxidized, and, although it would work up into a bloom which had the appearance of being good, when passed through the forge- rolls the bars would fracture through the sand not being properly deoxidized or cemented together. The directors got a rude awakening by receiving a report from Mr. John Coom, which showed that the iron was brittle and could not be sold as a first-class commercial article. The report reads as follows :— ' The iron was tested for tensile strength and by bending ; the steel was made into tools and used in wheel-turning and general work. ' Three pieces of the iron (marked ' A ' in the schedule) were drawn down to a sectional area of J in. ; the two pieces marked ' B ' were tested as sent from the works, the section of these being about 1 square inch. ' The apparatus used in testing is not one specially designed for the purpose : the results cannot, therefore, be looked upon as strictly accurate. ,c For your information I have shown results of some of Kirkaldy's tests of Bowling and Lowmoor iron, and the specification of the iron supplied for the Ohio (America) railroad bridge. No. of Piece. Brand. Mean Breaking -weight per Square Inch of Original Section. ( 'ontraction of Area at Fracture. Mean Elongation. Tons. Per Cent. Per Cent. 1 A 26-00 23-4 7-3 2 A 26-46 25-1 4-1 3 A 31-93 27-6 10-9 1 B 16-26 20-6 8-5 5 B 16-26 4-5 2-7 . . Bowling 27-86 45-3 29-4 ' • Lowmoor 27-59 53-1 26-5 . . Ohio River Bridge 26-75 25-0 15-0 specification 230 Transactions. ; The pieces 1, 2, and 3, which were drawn down from a large section, are superior to the pieces 4 and 5, which were tested in same section as received. " The results show the iron to be of a hard and unyielding character, but it evidently is improved by working ; it would require this before it could be safely used in engineering-works. The mean breaking-weight is high, but the contraction at the fractured area and the elongation are low, showing the iron to be as I state. " A further test of the iron was made by bending cold, and the results were fairly good : two pieces were bent double and showed but few cracks. ' The steel was made into tools for use in the wheel and other lathes ; these were given to the turners with instructions to use them for a week and then report. Their report was very favourable : they say the tools stood as well as most of those made from the imported article.'' The company then resorted to manufacturing wrought iron from scrap, but this was not profitable. First-class chemists were engaged in the labo- ratory, Mr. D. S. Galbraith working very hard in the hope of overcoming difficulties, but this was never done. The company struggled on until November, 1886, when, with its capital spent and a liability of £20,000, an attempt was made to reconstruct ; but the shareholders would not find money, and the assets of the company were taken over by the mortgagee. For a short time it was worked under tribute in the manufacture of bar iron from scrap, but this was never profit- able, and finally the plant was broken up and shipped to China, to be used there in new ironworks. So ended the most serious attempt at manufacturing iron from the sands of New Zealand, and one wonders now why it was not a success. Everything was done that could be thought of at the time by all con- cerned, for they were sanguine to the last, and hoped to retrieve the fortune spent in endeavouring to create a great industry for the Dominion. Art. XXV. — Notes on the Autecology of certain Plants of the Peridotite Belt, Nelson : Part I Structure of some of the Plants (No. 1). By M. Winifred Betts, M.Sc. Communicated bv Professor Benham, F.R.S. [Bead before the Otago Institute, 9th October, 1917 ; received by Editors, 29th December, 1917 ; issued separately, 24th June, 1918.] Introduction. At a short distance from the city of Nelson there is an area known as the ' Mineral Belt." This is a zone of boulder-strewn land-surface, often dun- coloured in appearance, underlain by peridotite and serpentine rocks, which extends from D'Urville Island, in Cook Strait, south-west for a distance of sixty miles. It is an almost continuous band, but it disappears for about a mile between the valleys of the Lee and Serpentine Rivers. At its nar- rowest part the Mineral Belt is 100 yards wide, and it reaches its maximum width of 3 miles 50 chains in the vicinity of the Dun Mountain. The area occupied by the Mineral Belt is about 29 \ square miles.* * J. M. Bell, E. de C. Clabke, and P. Marshall, The Dun Mountain Subdivision, N.Z. Gcol Sun: Bull. No. 12, 1911. Betts. — Avtecology of Plants of Peridotite Belt, Nelson. 231 The vegetation of the Mineral Belt presents a striking contrast with that of the neighbouring land-surface, which is clothed with luxuriant forests of southern-beech {Nothofagus spp.). On the Mineral Belt there are three principal plant-associations :- 1. Shrubland. — This is usually found near the margin of the Belt, and is composed of many species that are found in the adjacent forests, but on the Belt they are much dwarfed — e.g., Griselinia littoralis is usually a tree 10-16 metres high, but in the shrub formation on the Mineral Belt it is reduced to a woody shrub 3— 2 metres high; Nothofagus fusca, a forest-tree, is represented by small trees 2-3 metres high. In addition to these dwarfed representatives of the neighbouring forests there are in this association a number of shrubs which are not reduced. Such plants are Cassinia Vau- villiersii var.. Coprosma propinqua, Dracophyllum longifoliumvax., and Lepto- spermum scoparium var. In this association there are a number of small herbs — e.g., Glaytonia australasica, Colobanthus quitensis, and Epilobium pedunculate var. 2. Open Scrubland. —In this association the most characteristic plants are Cassinia Vauvilliersii var., Dracophyllum rosmarinifolium, Exocarpus Bidwillii. Hymenanthera dentata var. alpina, Veronica, buxifolia var., V. Menziesii var., V.pinguifolia^.), Pimelea Suteri, and Muehlenbeckia axillaris. Among the herbs to be found in this association are Myosotis Monroi, Notothlaspi australe, Gentiana corymbifera, Anisotome aromatica, and A. filifolium. 3. Tussock Grassland. — The' dominant plant is Danthonia Raoulii var. ; sub-dominant are Phormium Coohianum and Astelia montana var. It is proposed to describe the anatomy of a number of the plants of the Mineral Belt in a series of short papers, and then the results obtained from these investigations will be considered. In addition to the anatomy of the leaf and of the stem of the different species, a brief description of the growth-form of the plant is given. In those cases where the usual form of the species is found on the Mineral Belt this description is quoted from Cheeseman's Manual of the New Zealand Flora (1906). Where the species is modified in form, a description of the usual type is quoted, and then that of the plant as it is found on the Mineral Belt is given. 1. Nothofagus fusca Oerst. Usual Growth-form. '' A noble forest-tree 60-100 ft. high ; trunk 4-8 ft. diam. ; bark dark-brown or black in old plants, deeply furrowed, smooth and greyish- white on young trees ; branchlets and petioles pubescent. Leaves evergreen, petiolate, f-1^ in. long, broadly ovate or ovate-oblong, obtuse or rarely acute, cuneate at the base, rather thin but firm, pubescent above and glandular beneath when young, glabrous when old, deeply and sharply serrate, veins conspicuous; stipules linear-oblong, caducous."' Mineral Belt Growth-form. — A small tree 6-8 ft. high, with leaves |-f in. long. Anatomy. Leaf.- The upper epidermis consists of small cells, more or less oval in transverse section. The cell-walls are thin, except the external walls, which are slightly thickened and also cuticularized. Some of the epidermal cells, in the vicinity of the vascular bundles, are produced into long unicellular hairs which have thin, slightly cutinized walls. There are no stomates on the upper surface. The lower epidermal cells are small, oval, and thin-walled, the external walls being slightly thickened. A thin cuticle is present. Stomates are 232 Transactions. confined to the lower surface : the guard-cells are small and on the same level as the other epidermal cells, the stoma being protected by guard-cell ridges. On the lower surface there are hydathodes, which are sunk in slight depressions. The chlorenchyma is differentiated into palisade and spongy tissue. The former consists of 3 rows of thin-walled cells, the outer layer with the cells very closely arranged so that there are no intercellular spaces : the 2 inner layers are arranged more loosely. The spongy tissue consists of small thin -walled irregular cells which have rather small air-spaces between them. Manv of the chlorenchymatous cells contain tannin. The midrib is slightly prominent. Surrounding the vascular bundle of the midrib there is a sheath 1-3 cells thick, consisting of small sclerenchy- matous cells. Around this there is a sheath of larger cells, also with lignified walls. The xylem consists of vessels of moderately large diameter and of wood-fibres. Above the xylem there is a small amount of parenchyma. The phloem is in the form of a crescent : the parenchymatous elements contain tannin. Stem.- The cork is a fairly wide band of tissue, consisting of small, very compact cells. The cortical cells are large, and oval in transverse section. These cells are thick-walled, and many of them contain tannin. They are closely arranged, so that there are only small intercellular air-spaces. The pericycle fibres form a wide band, in which the cells vary consider- ablv in size in transverse section. Some are small, with their cell-walls so much lignified and thickened that the lumen is almost obliterated ; con- necting groups of these cells are much larger cells, also with thickened, lignified walls, but the cell-cavities are large. The phloem forms a narrow band, and the parenchyma contains tannin. The spring wood consists of a large number of vessels of large diameter, together with wood-fibres. The autumn wood is formed of much smaller vessels, and of wood-fibres in which the lumen is almost obliterated. The medullary rays are uniseriate, and the cells have thickened lignified walls, and contain tannin. The pith cells are large and round, have thick- ened lignified walls, and contain abundant starch. 2. Nothofagus cliffortioides Oerst. Usual Growth-form- "A small tree, usually from 20ft. to 40ft. high, rarely more, with a trunk 1-2 ft. diani., in alpine localities often dwarfed into a much-branched bush 5-12 ft. high. Branches spreading, often dis- tichous, especially in young trees : branchlets densely pubescent. Leaves shortly petiolate, distichous, |-| in. long, ovate-oblong or ovate or ovate- orbicular, acute or subacute, rarely obtuse, always broadest at the unequally rounded or almost cordate base, quite entire, very coriaceous, glabrous and reticulated above, more or less clothed with greyish-white appressed hairs beneath, margins thickened, often recurved ; stipules membranous, caducous." Mineral Belt Growth-form. A much-branched bush 4 8 ft. high, with leaves \-\ in. long. Anatomy. Leaf.— The upper epidermis consists of small cells which are more or less square in transverse section. These have their cell-walls thickened, and there is a thick cuticle. Some of the epidermal cells contain tannin. On the upper surface there are numerous glands which are formed from epidermal cells. Betts. — Aut ecology of Plants of Peridotiti Belt, Nelson. 233 The palisade and the spongy parenchyma, the lower epidermis, and the stomates are the same as in iV. fusca, but on the lower surface some of the epidermal cells are produced into unicellular hairs, which have thin non- cutinized walls. There is a thick cuticle on the lower surface. Many of the mesophvll cells and the cells of both the lower and the upper epidermis contain tannin. The vascular bundles are the same as in .V. fusca. but the midrib is smaller. Stem. — The structure is essentially the same as in N. fusca, the only differences being— (1) There are more pericycle fibres; (2) the phloem forms a wider band ; (3) the pith cells do not contain starch ; (4) there are more numerous vessels of large diameter. 3. Exocarpus Bidwillii Hook. f. Growth - form. - -" A small much - branched rigid procumbent shrub 6-24 in. high, branches ascending, short, stiff, terete, deeply furrowed. Leaves reduced to minute triangular scales, alternate, persistent." Fig. 1. — Exocarpus Bidwillii. Portion of plant (£ natural size). a. fruit ; b, leaves reduced to triangular scales. A portion of the plant is shown in fig. 1, which also shows the fruit, which is seated on the much-enlarged thickened red and succulent peduncle. The perianth-segments are persistent under the fruit. Anatomy. Stem (figs. 2-4). — The structure of the stem is shown roughly in fig. 2. From this it will be seen that the furrows are lined with stiff hairs, that there is a thick cuticle, &c. The more detailed structure of the stem is shown in fig;. 4. The epidermis consists of small squarish cells with thin cell-walls and an extremely thick cuticle. In the furrows the epidermal cells are larger and there is only a thin cuticle. Many of the epidermal cells in the furrows are produced into stiff hairs, which have thick walls which are cuticularized. In the furrows are the stomates, but these cannot be seen well in transverse section, as their long axes are placed transversely to the surface of the stem. 234 Transactions. Fig. 3 gives the epidermis from a longitudinal section ; from this it will be seen that the stomates are at the same level as the epidermal cells, and the opening is protected by guard-cell ridges. The cortex is composed of closely packed more or less polygonal cells with thin walls. In the outer part of the cortex, and especially in the Fig. 2. — Exocarpus Bidwillii. Diagrammatic transverse section of the stem ( x 24). a, thick cuticle ; b, furrow lined with hairs ; c, pericycle fibres. Fig. 3. — Exocarpus Bidwillii. Longitudinal section through epidermis ( X 350). a, guard- cell ridge. Fig. 4. — Exocarpus Bidwillii. Transverse section of stem (x 120). a, thick cuticle: b, tannin-containing cells ; c, chlorenchyma ; d, pericycle fibres ; e, phloem : /, vessels of xylem ; . Crab- beds with c< >nc id inns (greensands). fi. Grey marls. 7. White flaggy limestone and dark limestone. la. Ordinary limestone. S. Gravels. eight coal-seams, of an average thickness of 2 ft. The first of the marine sandstones occur as layers in sandy clays. These clays contain few fossils, but the sandstone is crowded with shells of Cardium waitakiense Sut. and Veneiicardia zelandica (Desh.) var. In the sandy clays there are layers of corals, chiefly Balanophyllia hectori T.-W. The overlying crab-beds have even fewer fossils than usual, but they are easily recognized by their colour and their numerous concretions, while an occasional crab may be found. Besides the latter, I collected Pecten huttoni (Park) and Panope sp. The marls, as usual, are practically devoid of fossils. The lower sands and sandstones overlying yielded a rich molluscan fauna, tabulated in column 1 of the table on page 259, and in Trans. N.Z. Inst., Vol. L. Plate XVI. Fig. 1. — View of the fluted limestone at Otaio Gorge. Almost the whole thickness of the limestone is shown in the photograph. Fig. 2. — Solutioivpits in the limestone on Holme Station, seen from the Gordon"s Valley -Little River Road. Face p- 350.] Trans. N.Z. Inst., Vol. L. Plate XVII. Fig. 1. — Road-tutting on Squire's Farm. The columnar structure of the loess is well seen. The lower part is a residual clay, passing into coarse gravels which lie on the limestone. Fig. 2. — The upper part of Little River Valley, viewed from Squire's Farm. The rock in the foreground is the uppermost part of the limestone, with soft layers. In the middle distance, on the left, the white flaky limestone is seen passing up into the dark and ordinary limestones, which in turn pass up into the blue clay. The wide river-terraces are well shown here. Gudex. — Succession of Tertiary Beds in Pareora District. 251 addition some fish-remains, echinoderm-spines. and the following corals : Flabellum sphenodeum T.-W., Balanophyllia hectoii T.-W., and Spite not melius huttonianus T.-W. The chalky limestone has no fossils excepl Foraminifera and other micro- scopic forms, while the dark limestone and the ordinary limestone have only a few brachiopods — viz., Pachymagas ellipticus Thomson and Aetkeia gualteri (Morris). Bluecliffs. Following the Otaio for four miles, we come to a long line of cliffs of blue clay, whence the district takes its name. These beds can be traced all the way from the Otaio Gorge, and are certainly resting on the limestone, though no actual junction is shown. The relation of the two beds, how- ever, is clearly seen at Squire's, Gordon's Valley, Cannington, and Mount Horrible. W.N.W. i st 5£S£ Fig. 4. — Section along Otaio River at Bluecliffs. Distance, about § mile ; direction, W.N.W.-E.S.E. ; dip, 20°. 1. Blue clays. 2. Lower part of the red sands, with concretions. 3. Middle part of the red sands, with calcareous sandstone. 4. Upper part of the red sands. 5. Gravels. The blue clays seem to reach their maximum thickness here, for they are at least 350 ft. thick (see fig. 4). The fossils occur very sparingly, but the great exposure of strata enables one to make a good collection. These bluish-green clays yield the molluscs tabulated in column 5 of the table of fossil mollusca, and in addition small nautiloids, annelids, scutes, and Pachymagas parki (Hutt.), Trochocyathus mantelli T.-W., Flabellum circulate T.-W., and F. laticostatum T.-W. Southburn Cutting. At the Southburn Cutting, at the end of the Bluecliff section, the blue clays are seen passing into red sands, with concretions. Higher up in these sands there are bands of calcareous sandstone. These beds are not richly fossiliferous, like the corresponding beds elsewhere, and in the highest part of the series there are no fossils at all. This exposure shows the sands to be very thick, probably 400 ft. at least, and I think that the uppermost part of them is the youngest marine formation in South Canterbury. From the sands, concretions, and sandstone layers I collected the molluscs tabulated in column 9 of the table of fossil mollusca, and in addition the brachiopod Pachymagas parki (Hutt.). Gordon's Valley. This valley begins near the western end of the exposure of blue clays at Bluecliffs, and passes first of all through the limestone, and then through the blue clays and red sands. The stratigraphy is clear, and shows the relations of the Pareora beds to the limestones. The upper part of the limestone at the head of the valley is more siliceous than usual, and has a fluted appearance due to the alternation of hard and soft layers. There are practically no fossils in the upper part, but in the lower part there are echinoids and crinoids, with a few brachiopods. 252 Transactions. Just below Mr. P. Elworthy's homestead the blue clays are seen over- lying the limestone and passing up into the red sands and sandstones. If the road from Gordon's Valley to Little River Valley be followed, first the blue clay and then the limestone will be passed over. In the valley leading down into Little River Valley the limestone is well exposed in cliffs 100ft. high. The lower parts contain many brachiopods, and a few other fossils, such as Epitonium browni (Zitt.), but the upper parts arc very siliceous, and in places there arc flint nodules which stand out like pegs from the weathered surfaces. The red sands have their usual characteristics : thus the lower part has concretions scattered through it, and then come alternating layers of hard sandstones and soft shelly bands. Above this there are the true red sands, with layers of shells, such as species of Venericardia, Polinices, Turritella, Limopsis, and Dentalium. These beds may be traced down to the back of the homestead at Holme Station. On the road over into Little River Valley, the solution - pits in the limestone can be seen. (Plate XVI, fig. 2.) From the limestone at this locality I collected Pericosmus compressus McCoy and Pentacrinus stellatus Hutt. The red sands yielded the molluscs tabulated in column 10 of the table of fossil mollusca. Squires Farm. (Plate XVII, figs. 1 and 2.) This locality is very important for showing the relationship between the Pareora beds and the underlying beds. Every member of Marshall's " Oamaru system " as developed in the Pareora district is exposed in the banks of the Little Pareora River where it flows through this farm. The grits of the coal series are very thick here, but the coal itself is not shown in any exposure. Pudding-stone conglomerates are interbedded with the 5W Fig. 5. — Section along right bank of Little River, in Squire's Farm. Distance, 300 yards ; direction, N.E.-S.W. ; dip, 40°. 1. Grits and sands of coal series. 2. Lowest fossiliferous sands. 3. Lower red sands, with calcareous sandstones. 4. Red sands. 5. Crab- beds (seen in the bed of the river), (i. Grey m ails (seen in the bed of the river). 7. White flaky limestone and dark limestone. 8. Limestone, current-bedded. 0. Gravels. grits. The lowest fossiliferous beds are found near the top of the land- slip facing the road to Otaio Gorge. They are strongly impregnated with iron oxides, which have replaced the fossils, so that only casts can lie obtained. The harder bands stand out as reefs and ridges on the hillside. The fossils obtained were Dosinia lambata (Gould). Pecten huttoni (Park), Chione sp., and Polinices sp. The crab-beds and marls are not exposed on the hillside, but they appear in the bed of the river near the sharp turn in the river. They may be described as typical greensands with concretions, but usually these beds are rather too brown and marly to be called " greensands." They yielded Pa nope worthingtoni Hutt. and Turritella sp. Gudex. — Succession of Tertiary Beth in Pareora District. 253 The next bed exposed consists of a white limestone, which breaks into small cubes and flakes similar to those found in the A mini limestone at Weka Pass. This limestone is seen in the bed of the river for more than a quarter of a mile, and is well exposed in a section on the right bank. Its greatest thickness in an exposure is 14 ft., but it may really be as much as 20 ft. Near the top its uniform texture changes, and the rock assumes a speckled appearance, due to the presence of tubes or pipes rilled with grey limestone, similar to that found in the overlying stone. There is no erosion surface or other sign of unconformity, so that the change in the character of the rock was due to a change in the conditions of deposit. Some of the tubes appear to be worm-borings, but most of them are too large for such an origin. The dark limestone is 4 ft. 6 in. thick in one section, but its thickness varies. In places it is indistinguishable in colour from the ordinary lime- stone, but it is always softer and more arenaceous, and it contains more fossils. In the first exposure seen on Squire's Farm this limestone is crowded with brachiopods, and sharks' teeth are common in " pockets." Fig. 6. — Section across Little River, in Squire's Farm. Distance, about 180 yards; direction, S.S.W. - N.N.E. ; dip, 25°. 1. White flaky limestone. 2. Dark limestone. 3. Limestone. 4. Limestone with soft iayers, passing into blue clay. .3. Blue clay. 6. Lowest horizon of upper red sands, with large concretions. 7. Gravels. The uppermost layer, about 1 ft. thick, contains frequent specimens of Lima (Plagiostoma) laevigata Hutt. and Pecten huttoni (Park). In many of the fossils, the carbonate of lime is replaced, wholly or partly, by iron oxides. The complete list of fossils collected is as follows : Epitonium lyratum (Zitt.), E. browni (Zitt.), Lima laevigata Hutt.. Pecten huttoni (Park), P. scandula Hutt. (?), Echinus sp., Eupatagus greyi Tate, E. tuberculatum Zitt., Balanus sp., Aetheia gualteri (Morris), Pachymagas eUipticus Thomson, Rhizothyris rhizoida (Hutt.), Liothyrella landonensis Thomson, Lamna huttoni Davis, L. incurva Davis, Oxyrhina grandis Davis, and Kekenodon onomafa Hector (?). The ordinary limestone affords a fine example of current-bedding, and this fact, taken in conjunction with the arenaceous nature of the rock and the number of quartz grains seen in a microscopic slide, shows that the deposit was not formed in deep water. The fossils obtained from the ordinary limestone were: Epitonium, lyratum (Zitt.), E. browni (Zitt.), Lima laevigata Hutt., L. paleata Hutt. (?), Pecten huttoni (Park), P. williamsoni Zitt., Atrina zelandica Gray, Eupatagus greyi Tate. Pericosnvus compressus McCoy, Pentacrinus stellatus Hutt., Cidaris spines, Retepora (?), Graphularia sp., Aetheia gualteri (Morris), Liothyrella landonensis Thomson, Terebratu- lina suessi Hutt., Rhizothyris rhizoida (Hutt.), Pachymagas huttoni Thomson, P. parti (Hutt.), and Hemithyris nigricans (Sow.). 254 Transactions. Farther down the river the white flaggy limestone appears in the left bank, but most of the dark limestone is covered with shingle. The ordinary limestone is well shown, but it has even fewer fossils than usual. The section is perfectly clear, and shows the limestone passing very gradually into the blue clay. The transition is marked by alternations of hard and of soft layers. There is a small reversed fault here, with an upthrust of 2 ft. and a hade of 5°. In the first interbedded soft band a small nautiloid, Pecten huttoni (Park), Pachymagas parki (Hutt.), and species of Flabellum are almost the only fossils. In the first horizon of the blue clay proper the commonest fossils are species of Flabellum and Trochocyathus, and Limopsis aurita Brocchi. In the creek-bed many small species are found, such as Alectrion socialis (Hutt.) and Corbula canaliculata Hutt. At the foot of the landslip the ordinary fossils of the blue clay appear ; of these Pecten zitteli Hutt. is more common than usual. A list of the molluscs obtained is given in column 6 of the table, and in addition the following were found : a small nautiloid, Pachymagas parki (Hutt.), Flabellum circulare T.-W., Trochocyathus mantelli T.-W., a scute (?), and whale-bones. Near the top of the slip, in the little patch of bush, the blue clays are seen passing into red sands with concretions. These beds are best seen on the right bank a little below the slip, and the middle and upper horizons are seen half a mile down the river on the left bank. The following fossils were collected : TurriteUa semiconcava Sut., Polinices ovatus (Hutt.), P. gibbosus (Hutt.), Siphonalia 'costata (Hutt.), Ancilla hebera (Hutt.), Surcula fusiformis (Hutt.), Pecten huttoni (Park), Venericardia pseutes Sut., Nucula sagittata Sut., and Chione meridionalis (Sow.). Owing to the smallness of this collection, it so happens that no Recent species were found here, but the character of the beds, the stratigraphy, and the nature of these fossils all show that these are the ordinary upper red sands. The loess is well shown in the saddle between the Otaio Gorge and Little River, and in a cutting made for a new road through Squire's Farm. (See Plate XVII, fig. 1.) White Rock. Here only the upper beds of the series are exposed, but their rich fauna has made them very important. The beds show the effects of gentle folding, for the dip alters gradually as we go westwards. There is an interesting occurrence of a lignite in these beds. It does not belong to the coal series, but seems to be almost contemporaneous with the marine fauna found in the ordinary layers. The fossils are found in wonderful profusion in a few narrow layers, but they seem to follow exactly the same order as at Sutherland's. Thus the struthiolarias are confined almost wholly to the upper layer, while the flat lamellibranchs, such as Zenatia acinaces (Q. & Gr.), Chione speighti Sut., &c, are confined to the lower. The molluscs collected are given in column 11 of the table, and in addition Myliobates sp. and Arachnoides placenta were obtained. Mount Horrible (Pareora River). At the foot of Mount Horrible the river has exposed the limestone, the blue clay, and the red sands. The limestone clearly underlies the blue clay, which in turn passes up gradually into red sands. The limestone at the kiln is very siliceous, with flint nodules. The blue clays are well exposed in the slip at the Fishermen's Huts, and can be followed down the left bank of the river for about one mile and a half. The red sands are found at the level of the water-race above the slip, and in a gully which runs up Gudbx. — Succession of Tertiary Beds in Pareora District. 255 towards the dolerite. The highest exposure of the red sands occurs about 20 ft. below the dolerite, but, as at Sutherland's and Southburn Cutting, the uppermost beds are devoid of fossils. The intermediate parts of the red sands — namely, those with concretions and layers of shelly sand- stones— are not well exposed on the left bank, but they appear on the other side of the valley, in Holme Station. N.W. SE. Fig. 7. — Section across south-west corner of Mount Horrible. Distance, about l£ miles; direction, N.W. - S.E. ; clip, 15°. 1. Limestone. 2. Blue clays. 3. Red sands. 4. Gravel. 5. Ash. 6. Dolerite. 7. Talus. From the blue clay I collected the molluscs tabulated in column 7 of the table, and in addition Pachymagas parki (Hutt.), Flabellwm circulare T.-AV.. F. laticostatum T.-W., Trochocyathus mantelli T.-W., and annelid-tubes. From the upper red sands I obtained Ampullina suturalis (Hutt.), Hetm- conus trailli (Hutt.), and Chione sp. Cave ami Sutherland's. The beds exposed in these two localities are — the lower sands and sandstones, the crab-beds and marls, the limestone, the blue clay, and the upper red sands. The sequence is exactly the same as at Squire's. Farm. Mount Horrible, and Cannington. The lower red sands are seen in the right bank of the Tengawai, a quarter of a mile above the railway- station. They contain only a few fossils, as they are the uppermost horizon ; the lower horizons, with corals, have not yet been cut into by the river. In one exposure these sands show current-bedding. K y _tT-<' fs t"J\ N Fig. 8. — Section across Tengawai River, at Cave. Distance. \ mile ; direction, N.-S. ; dip, 35°. 1. Greywacke. 2. Sands. 3. Crab- beds (greensands) with concretions. 4. Marls. ' 5. Dark arenaceous lime- stone. 6. Ordinary limestone. 7. Gravel-. The crab-beds and marls are well exposed on the left bank, above Cave. They have their usual lithological character, but the concretions contain molluscs, chiefly lamellibranchs, instead of crabs. On the left bank the marls are seen to be overlain by a dark arenaceous limestone, which is thicker than usual. From the surface of contact I collected Lima imitata Sut. and various pectens. The limestone is also seen in the bed of the river and in the right bank at the bridge. Just below the bridge I col- lected a number of fossils from the limestone. Fine exposures are found 256 Transactions. on the left bank, where the limestone forms cliffs over 80 ft. high. Still farther down there is an exposure of the limestone close in against the greywacke. This would seem to have been faulted down, but the throw of the fault could not have been very great. In the quarry there are two faults, with slickensides, and much of the limestone appears to have been crushed and deformed by pressure. The blue clay is seen in the river-bed at the new bridge leading to Totara Valley, and in the terrace south of the railway-line, where the road passes over to Tycho Flat. Half a mile farther down the red sands are well exposed beside the railway. The upper portions of the red sands are exposed all along the valley at the back of the school, but the fossil- iferous horizons are not well exposed there. Near the railway-line the first beds are brown sands, with calcareous sandstone in layers. These sands change to very red sands, with practically no fossils. Again the beds are brown, with no fossils. The first layer of sandstone in this horizon is crowded with species of Psammobia and other flat shells, and Polinices and Natica. The top layer has many specimens of Turritella cavershamensis Harris, and species of Struthiolaria, Glycymeris, and Dosinia. There are also two soft shelly layers crowded with Turritella cavershamensis Harris, as at White Rock. This is the horizon of Latirus brevirostris (Hutt.) and Hemiconus trailli (Hutt.). Except for the difference in colour, the beds are exactly similar to those of White Rock. From the lower red sands (Waihao beds) I obtained the following : Turritella cavershamensis Harris, T. symmetrica Hutt., Struthiolaria sp., Polinices gibbosus (Hutt.), Ancilla hebera (Hutt.), Cardium waitakiense Sut., and Glycymeris laticostata (Q. & G.). The crab-beds at Cave yielded Cucullaea alta Sow., Chione meridionalis (Sow.), and Limopsis aurita (Brocchi). I collected from the limestone at Cave Ampullina sp., Pecten williamsoni Zitt., P. burnetii Zitt.. P. huttoni (Park), Lima (Acesta) imitata Sut., Ostrea sp., Pachymagas parki (Hutt.), P. huttoni Thomson, Liothyrella gravida (Suess), Rhizothyris rhizoida (Hutt.), Terebratulina suessi Hutt., Balanus sp., Pentacrinus stellatus Hutt., Pericosmus compressus McCoy, and Eupatagus tuberculatus Zitt. The upper red sands at Sutherland's yielded the sixty-four species of molluscs tabulated in column 12 of the table. Little River and the South-west End of Craigmore. On the banks of the Little River and its chief tributary there are fine exposures of all the beds from the quartz grits up to the limestone. The grits and sands of the coal series are typically developed above the junc- tion of the two streams, but the coal is represented by a narrow band of carbonaceous clay. The lowest Tertiary bed consists of pipeclay which was laid down on the eroded surface of the Mesozoic rocks. The grits are snow-white in most of this locality. The lower sands and sandstones are seen lying on top of the grits, but they are not so fossiliferous as at Otaio Gorge. Below the junction these beds are found in the river-bed, and consist of sands with bands of con- cretionary sandstone and layers of soft crumbly shells. The commonest fossils in this exposure are Venericardia zelandica (Desh.) var. and Turritella symmetrica Hutt., and a few specimens of Ostrea gudexi Sut. may be found. The lower sands and sandstones are exposed all along the left bank until the end of the valley is reached, and they appear in the cuttings on the road that passes above the Pareora dam. (Judex. — Succession of Tertiary Beds in Paredra District. 257 The crab-beds are well seen half-way up the hill on the left bank of the tributary, and have their usual character. The concretions contain a few crabs, while specimens of Cucullaea alia Sow., partly replaced by iron compounds, are found scattered through the beds. The crab-beds may be followed all along the Little River Valley, first on the left bank, then in the bed of the river, and then along the right bank until the lime-kiln is approached. One mile above the kiln the crab-beds are seen passing up into marls of a greenish-grey colour. These are the " grey marls " described by McKay. The same beds are seen in the left bank, above the bridge. YiG. 9. — Section along left bank of main tributary of Little River, above the junction Distance, f mile ; direction, N.W.-S.E. ; dip. 10°. 1 . Trias-Jura. 2. Pipeclay. 3. White quartz grits, with carbonaceous shales. 4. Sands with calcareous sandstone. 5. Crab- beds (greensands) with small con- cretions. 6. Marls, grey at the top. 7. Limestone. The limestone forms the crown of the Craigmore Block, and appears on Holme Station at a lower level. It exhibits folding at both ends of Craigmore, where an anticlinal structure appears. At the north end, in a section S.S.W.-N.N.E., the dip is 10° to the south-south-west; and still farther on, in a section W.-E., the dip is 40° to the west ; while in a section at the crest, running west and east, the dip is 0°. The eastern limb has been almost completely shorn away by the action of Little River, but the limestone on Holme Station and in Mount Horrible enables us to reconstruct the anticline. At the south-west end of Craigmore the struc- ture is not quite so clear, chiefly because the anticline dies away in the next mile or two, and is followed by an unsymmetrical syncline in the direction of Squire's Farm. There is a small, superficial fresh-water deposit on the left bank of Little River, about two miles above the bridge, and from it I collected specimens of a fresh-water gasteropod which Mr. Suter says is new. The lower red sands and sandstones yielded Polinices suturalis (Hutt.), Typhis maccoyi T.-W.. Volutospina sp., Crassatellites obesus (A. Ad.), and Astarte ? sp. From the crab-beds on the left bank I collected Struthiolaria tuberculata Hutt., Ancilla hebera (Hutt.), Surcula fusiformis (Hutt.), Cucullaea alta Sow., C. attenuata Hutt., Atrina zelandica (Gray), Ostrea sp., and Macro- callista assimilis (Hutt.). From the upper crab-beds, one mile above the lime-kiln, I obtained Turritella symmetrica Hutt., Polinices gibbosus (Hutt.), Ancilla sp. now, Dentalium solidum Hutt., Crassatellites obesus (A. Ad.), Ostrea nelsoniana Zitt., Gryphaea tarda Hutt., Pecten (Chlamys) williamsoni Zitt., P. hilli Hutt., P. huttoni (Park), P. delicatulus Hutt., Pecten sp. nov. between triphooki and zelandiae, Macrocallista assimilis (Hutt.), Teredo directa Hutt.. Holaster sp., and Cidaris spines. 9— Trans. 258 Transactions. Craigmore. At the north end of Craigmore there is an exposure of the whole series of Tertiaries from the quartz grits to the limestone. The grits are resting on the Mesozoic rocks, which have been cut down to a dej)th of about 300 ft. by the Pareora River. The marine sandstones, as usual, contain layers of Cardium waitakiense Sut. and Venericardia zelandica (Desh.) var. The limestone which forms the crest of Craigmore occupies the summit of an anticline, which pitches west to form the Upper Pareora basin. From the limestone I collected Epitonium lyratum (Zitt.), E. browni (Zitt.), Pecten huttoni (Park), Lima laevigata Hutt., Aetheia gualteri (Morris), Terebratulina suessi Hutt., Rhizothyris rhizoida (Hutt.), Liothyrella landonensis Thomson, Pachymagas parki (Hutt.), Flabellum radians T.-W., F. circulare T.-W., Retepora sp., Graphularia sp., Eupatagus tuberculatus Zitt., E. greyi Hutt., Pericosmus lyoni Tate, P. compressus McCoy, Pentacrinus stellatus Hutt., Oxyrhina grandis Davis, Lamna huttoni Davis, L. incurva Davis, and Keke- nodon (?). Tycho Valley. Along the right bank of this valley there is a steep limestone slope, and in one place this is overlain by a deposit of blue clay, which is the only evidence that all this limestone was once covered by the blue clay. From the clay I collected Chione meridionalis (Sow.), Crassatellites obesus (A. Ad.), and Limopsis aurita (Brocchi). Holme Station. In this locality the upper red sands and sandstones are seen dipping- south-east at 15°. The lowest beds have few fossils, but the upper beds contain concretions and hard calcareous layers, as at Southburn Cutting and Gordon's Valley. They contain a rich fauna, and it is noteworthy that this is the exposure from which the first " Pareora " fossils were collected. I collected here the sixty-nine species of molluscs tabulated in column 13 of the table. Cannington. The only Tertiary beds exposed here are the limestone, the blue clay, and the upper red sands. The section is noteworthy, as the beds dip into instead of away from the Trias-Jura rocks. The limestone is well seen on the right bank, where it dips in one section to the north-north-east at 40°, and in another section to the north-north-west at 10°. Fig. 10. — Section along left bank of Pareora River, near the upper gorge (Cannington). Distance, about f mile ; direction. S.S.E. -N.N.W. ; dip, 10°. 1. Greywacke. 2. Limestone. 3. Blue clay. 4. Gravel. (The westerly part of the section is obscured by gravels.) On the left bank the limestone is followed conformably by blue clays, as at^Squire's Farm, but heavy deposits of gravel have obscured the upper Gudex. — Succession of Tertiary Beds in Pareora District. 259 parts of the section. About a mile farther down, however, the red sands are seen in the cuttings made for the road that passes over the steep hill on the left bank. The limestone yielded Epitonium lyratum (Zitt.), E. orowni (Zitt.), Pachymagas sp., echinoderm spines and plates, and Pentacrinus stellatus Hutt. From the blue clay lying only a few feet above the limestone I collected TurriteUa concava Hutt.. Crcpidula gregaria Sow., Pplinices sp., Surcula fusiformis (Hutt.), Dentalium mantelli Zitt., D. ecostatum T. W. Kirk, Malletia austral is (Q. & G.), Pecten huttoni (Park), P. zitteli Hutt., Chiorte meridionalis (Sow.). Chiorte chiloensis truncata Sut., Limopsis aurita (Brocchi), Corbula canaliculate Hutt., Cochlodesma angasi (C. & F.) (?), and Pachymagas parhi (Hutt,). Ford's, Fenn's, and PringWs. If we follow the road along the foothills, from Squire's Farm to White Rock, we find that almost the only Tertiary beds exposed are the grits of the coal series. Between Squire's Farm and the first tributary of Little River, however, a marine sandstone is found in one of the road-cuttings, and farther on there is a small outcrop of limestone on the left of the road. This limestone lies close in against the greywacke, and its position is hard to account for, unless it has been faulted down. From the sandstone I collected the following fossils : TurriteUa sym- metrica Hutt., Ancilla australis (Sow.), Psammobia lineolata Gray, P. zelandica Desh., Venericardia pseutes Sut., V. zelandica (Desh.) var., Macrocallista assimilis (Hutt.), Modiolus dolichus Sut., and Cardium waitakiense Sut. Table of Fossil Mollusca. (Recent species are marked with an asterisk before the name ; complete faunas of formations throughout the district are followed by a double rule.) Column 1 . Column 2. Column Column Column Column Column Column Column Column 10. Column 11. Column 12. Column 13. Column 14. Column 15. Lower sands and sandstones, Otaio Gorge. Complete fauna of lower sands and sandstones (Waihao beds) throughout the district. Complete fauna of crab- beds and marls throughout the district. Complete fauna of the limestones throughout the district. Bluish-green clays, Bluecliffs, Otaio River. Blue clays, Squire's Farm. Blue clays, Pareora River, foot of Mount Horrible. Complete fauna of blue clays throughout the district. Upper red sands with concretions, Southburn Cutting. Upper red sands, Gordon's Valley. LTpper beds of the series. White Rock River. Upper red sands, Sutherland's. Upper red sands, Holme Station. Complete fauna of upper red sands throughout the district. Complete fauna of the Pareora series (columns 8 and 14). 1. I 2. 3. 6. 8. 9. 10. 11. i 12. 13. 14. 15. Alectrion social is (Hutt.) Ampullina suturalis (Hutt.) Amusium zitteli (Hutt.) * Ancilla australis (Sow.) * .. depressa (Sow.) „ fabera (Hutt.) * „ novae-zelandiae (Sow.) „ papillata (Tate) „ waikopiroensis Sut. 9* x X X X X X . . X X Cf. X X X X X X X X X X .. X X X .. X X X . . X .. X X X X X X 1 X X X X X X X X X X X X . . X X . . X . . X X X X X X X X X X X X X X X X 260 Transactions. 3. 4. 5. 6. 1 7. 8. 9. 10. 11. 12. 13. 14. 15. Archilectonica cf. ngaparaensis Sut. Astarte australis Hutt. (?) ,, sulcata (Hutt.) Borsonia cincta (Hutt.) Bulla sp. ( ?) . . *Calyptraea alia (Hutt.) * ,, maculata (Q. & G.) . . * „ „ inflata (Hutt.) Cardium greyi Hutt. . . „ waitakiense Sut. C'erithiutn hector i Harris Chione acuminata Hutt. „ chiloensis truncata Sut. . . „ meridionalis (Sow.) „ speighti Sut. *Cochlodesma angasi (C. & F.) (?) Cominella carinata (Hutt.) „ pulchra Sut. Corbula canaliculata Hutt. Crassattllit.es amplus (Zitt.) * „ obesus (A. Ad.) *Crepidula costata (Sow.) „ gregaria Sow. * ,, monoxyla (Less.) ., striata (Hutt.) Cucullaea alta Sow. „ attenuata Hutt. „ australis (Hutt.) Cylichnelki eny •si (Hutt.) G'ymatium minimum (Hutt.) Cytherea enysi Hutt. Daphnella neozelanica Sut. *Dentalium ecostatum T. W. Kirk „ mantelli Zitt. * „ nanum Hutt. ,, solidum Hutt. . . *Divaricella cumingi (Ad. & Ang.) *Dosinia greyi Zitt. * „ lambata (Gould) „ magna Hutt. Drillia awamoaensis (Hutt.) ,, buchanani (Hutt.) Epitonium browni (Zitt.) ,, elatum Sut. „ lyratum (Zitt.) * ,, zelebori (Dkr.) Euthria media (Hutt.) Exilia dalli Sut. Ficus transennus Sut. . . Fulgoraria aculeata (Hutt. ) * „ arabica (Mart.) „ „ elongata(Swainn. ) „ „ turrita Sut. ' „ gracilis (Swains.) *Fnsinus spiralis (A. Ad.) X X X X X X X X X X X X X X ? X x X X X X X X X X X X X X ? X " •• X X X X X X .. •• •• i ' ' X X X X X X X X X x x • • >< x x X X X X X X X X X X X X X X X X X X •• X X X X X X X X X X X X X X X X X 9 X X X X X X X X X X X X X X X X X X X X 9 X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X 1 X 1 X X X X X X X X x X X X X X X X X X X X X X X X X X X X X X X X X X x X X X X X X X X x i X X X X X X X X X X X X X X X X X X X X X X X X X X X x X X X X X X X X X X X X X x X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X x X X X 1 X X ! X X X X X X i x X X X X X X X X X X X X X X X Gtjdex. — Succession of Tertiary Beds in Pareora District. "2(J1 1. 2. 3. 4. 5. 6. 7. 8. 1 9. 10. 11. 12. 13. 14. 15. Galeodea senex (Hutt.) Genota robusta (Hutt.) Glycymeris cordata (Hutt.) ,, globosa (Hutt.) * ,, laticostata (Q. & G.) . . Gryphaea tarda Hutt. .. Heliacus impcrfectua Sut. Hemiconus ornatus (Hutt.) Latirus brevirostris (Hutt.) Leucosyrinx alta (Harris) Lima colorata Hutt. ,, imitata Sut. ,, laevigata Hutt. ., -paleata Hutt. (?) *Limopsis aurita (Brocchi) ,, catenata Sut. ,, zitteli Iher. Loripes laminata Hutt. Macrocallista assimilis (Hutt.) . . Mactra chrydea Sut. * „ discors Gray * „ scalpellum Reeve * Mallet ia australis (Q. & G.) *Mangilia protensa (Hutt.) Marginella conica Harris Mesalia striolata (Hutt.) Miomelon corrugata (Hutt.) Mitra armorica Sut. Modiolus dolichus Sut. Murex zelandicus Q. & G. *Natica australis (Hutt.) * .. zelandica Q. & G. *Niicula nitidula A. Ad. Olivella neozelanica (Hutt.) Ostrea gude.ri Sut. „ nelsoniana Zitt. Panope orbita (Hutt.) . . „ worthingtoni (Hutt.) * ,, zelandica (Q. & G.) Paphia curta (Hutt.) .. Pecten bumetti Zitt. . . „ delicatulus Hutt. hilli Hutt. ,, huttoni (Park) . . „ scandiila Hutt. (?) „ cf. triphooki Zitt. ,, williamsoni Zitt. Placunanomia incisura Hutt. * ,, zelandica (Gray) *Polinices amphialus (Wats.) „ gibbosus (Hutt.) ,, huttoni Iher. ,, ovatu? (Hutt.) ,, phtnispirus Sut. * Psammobia lineolata Gray ,, cf. stangeri Gray * ,, zelandica Desh. Ptychatractus nodosoliratus Sut. *Pupa alba Hutt. Sinum cinctum (Hutt.) ,, miocoenicum (Sut.) „ undulatum (Sut.) X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X / X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X x X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X x X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X 262 Transactions. 1. 2. !| 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. Siphonalia conoidea (Zitt.) ,, costata (Hutt.) * „ dilatata (Q. & G.) ,, nodosa (Mart.) . . „ subnodosa (Hutt.) Strnthiolaria cincta Hutt. „ papulosa (Mart.) . , ,. spinosa Hect. ,, tuberculata Hutt. . . Surcula fusiformis (Hutt.) *Tellina glabrella Desh. Terebra orycta Sut. „ pareoraensis Sut. * „ tristis Desh. Teredo heaphyi Zitt. . . . . ,, directa Hutt. Turbonilla prisca Sut. *Turritella carlottae Wats. „ cavershamensis Harris „ concava Hutt. „ patagonica Sow. * ,, rosea Q. & G. ,, semiconcava Sut. * ,. symmetrica, Hutt. Typhis maccoyi T.-W. Venericardia pseutes Sut. * „ purpurata (Desh.) . . „ zelandica (Desh. ) var. Vexillum apicale (Hutt.) „ rutidolomum Sut. *Zenatia acinaces Q. & G. X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X x X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X X Bibliography. Haast, J., 1865. Report on the Geological Formation of the Timaru District, in reference to obtaining a Supply of Water, 1 3 pp., and sections, Christchurch. Hardcastle, J., 1 890. Origin of the Loess Deposit of the Timaru Plateau. Trans. N.Z. Inst., vol. 22, pp. 406-14. ■ 1891. On the Drift in South Canterbury, Trans. N.Z. Inst., vol. 23, pp. 311-24. 1891a. On the Timaru Loess as a Climate Register. Trans. N.Z. Inst., vol. 23, pp. 324-32. — — 1908. Notes on the Geology of South Canterbury, 62 pp.. Timaru. Hutton, F. W.. 1873. Catalogue of the Tertiary Mollusca and Echinodermata of New Zealand in the Collection of the Colonial Museum (ref. to pp. vii, viii). Mantell, G. A., 1850. Notice of the Remains of the Dinornis and other Birds, and of Fossils and Rock-specimens, recently collected by Mr. Walter Mantell in the Middle Island of New Zealand. Quart. Journ. Geol. Soc, vol. 6, pp. 319-42 (ref. to pp. 322-23). Marshall. P., 1916. The Yoimger Limestones of New Zealand, Trans. N.Z. Inst., vol. 48, pp. 87-99. McKay, A., 1877. Oamaru and Waitaki Districts, Rep. Geol. Explor. dur. 1876-77, pp. 41-66. Park, J., 1905. On the Marine Tertiaries of Otago and Canterbury, with Special Reference to the Relations existing between the Pareora and Oamaru Series. Trans. N.Z. Inst., vol. 37, pp. 489-551. Speight, R., 1914. Additions to the List of Fossils from the Lower Waipara, Trans. N.Z. Inst., vol. 46, p. 300. Thomson, J. A., 1914. Classification and Correlation of the Tertiary Rocks, 8th Ann. Rep. (n.s.) N.Z. Geol. Surv., pp. 123-24. 1917. Diastrophic and other Considerations in Classification and Correlation, and the Existence of Minor Diastrophic Districts in the Notocene, Trans. N.Z. Inst.'vol. 49, pp. 397-41 3. Marshall. — Tertiary Molluscan Fauna of Pakaurangi Point. 263 Aet. XXVII. — The Tertiary Molluscan, Fauna of Pakaurangi Point. Kaipara Harbour. By P. Marshall, M.A., D.Sc. [Read before thr Wanganui Philosophical Society, 19th December, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 24th June, 1918.] Plates XVIII XXII. In a previous paper* a list was given of the Mollusca that had been collected in this locality. Further collections have since been made which have added considerably to the number of the species. Descriptions and figures are given of all the new species. A discussion of the nature of the fauna will be given after the descriptions. Vaginella torpedo n. sp. (Plate XXII, figs. 7, 8.) Shell of moderate size, 18 mm. by 3"5 mm. Form cylindrical with a conical termination. Slightly compressed at the anterior end. Shell por- cellanous with a shining surface. With a low-power pocket-lens a series of fine longitudinal lines can just be made out. Seven good specimens were obtained. Type in the Wanganui Museum. Calliostoma gracilis. (Plate XVIII, figs. 1, la.) Shell small : height, 7 mm. ; breadth, 10 mm. : trochoidal. Spire short, of 3 whorls. Aperture oval. Columella slightly excavated. Protoconch consisting of 2 whorls. Outline of each whorl of the spire slightly concave. Three small spiral threads near the posterior suture of each whorl and a larger one near the anterior suture. Body-whorl with a large number of fine spiral threads in addition to those on the other whorls. Base with similar small spiral lines, with two large and prominent ones that divide the base into three approximately equal parts. Inner layer of the shell highly nacreous. One specimen, in good condition. Type in the Wanganui Museum. Heliacus aucklandicus. (Plate XVIII, figs. 2, 2a.) Shell small : height, 3 mm. ; breadth, 10 mm. Form obtusely conical. Spire short, consisting of 5 whorls each with a straight outline. Aperture regular. Umbilicus very large, with a strongly crenulated margin. Orna- mentation : Each whorl with 4 beaded cinguli ; the two most prominent of these border the anterior and posterior sutures closely. Base smooth except for irregular ribs radiating outward from the crenulated margin of the umbilicus. One specimen only, in a good state of preservation. Type in the Wanganui Museum. Epitonium tricinctum n. sp. (Plate XIX, figs. 8, 12.) Shell small and slender : length, 8 mm. ; breadth, 3 mm. Spire of 6 whorls, but it is not complete. Outline of whorls strongly convex. Suture deep. Aperture not preserved. Ornamentation : On each whorl 3 strong spiral lines. The uppermost of these is the most prominent : it is situated * Tran*. N.Z. hist., vol. 49, pp. 447-48, 1917. 264 Transactions. a little behind the middle of the whorl, and the other two lie between it and the suture in front. Each of the spiral lines is continuous over the radial lines, of which there are 18 in each whorl. Only one specimen was found, and it is somewhat incomplete, but the ornamentation is quite distinct from that of any other New Zealand species. Type in the Wanganui Museum. Fusinus corrugatus n. sp. (Plate XXII, figs. 9, 10.) Shell of moderate size, fusiform, 21 mm. by 5 mm. Spire a little less than half the length of the shell, consisting of 6 whorls, each strongly convex. Aperture oval, and narrowing anteriorly' into a moderately long canal. Protoconch of 3 whorls, smooth. Ornamentation : 7 rounded axial costae in each whorl, extending from suture to suture, but much higher on the keel than elsewhere. Spiral threads some 6 in number in each whorl but extremely unequal, the one that marks the keel being much more pro- minent than all the others, and the one anterior to it also much larger than the rest. The spiral lines are particularly strong on the costae, where they form prominent projections. Very small spiral threads between every pair of larger ones. Suture not pronounced, wavy. Body-whorl with similar ornamentation, the spiral lines being continued to the end of the beak, but they are much less prominent there. Two specimens, one almost complete, the other without its beak. Type in the Wanganui Museum. Dolicholatirus (Pseudolatirus) ornatus n. sp. (Plate XVIII, figs, 3, 3a.) Shell of moderate size, 25 mm. by 10 mm. Shape fusiform. Spire of 6 whorls, protoconch of 2 whorls. Suture compressed wavy. Aperture pyriform, almost half the total length of the shell, and produced anteriorly into a long canal but somewhat truncated posteriorly. Outer lip thin, with 12 internal projections. Columella slightly bent inwards where the aperture narrows into the anterior siphon. Columella slightly callous, smooth but furnished with 5 small projections, 2 of which are the terminal points of columellar folds. At the base of the aperture 3 small pro- jections. Ornamentation : 7 prominent radial costae on each whorl. The costae in successive whorls are not arranged in a straight line but form a spiral directed backwards. Each whorl with a large number of spiral threads. About every fourth thread is much larger and forms prominent elevations where they cross the costae. Strong lines of growth. On the body-whorl the costae extend to the beginning of the anterior canal. Six specimens. Type in the Wanganui Museum. Siphonalia flexuosa n. sp. (Plate XXII, figs. 11, 12.) Shell of moderate size, of oval shape, 28 mm. by 17 mm. Spire of 6 whorls rapidly decreasing in size. Aperture rather less than half the length of the shell. Outer lip moderately thick and ornamented internally by several short spiral lines. Anterior canal bent sharply to the right and of moderate length. Ornamentation : 10 radial costae on each whorl : these extend to the anterior suture but barely reach the posterior one : they are more distinct in the upper whorls. Suture strongly margined anteriorly. Posterior portion of each whorl concave in outline. All parts of the whorls have spiral ribs, which are large and rounded. There is usually one small thread between each pair of ribs. Large spiral threads are less pronounced on the beak, and the interstitial threads are more numerous. Growth- lines are numerous and conspicuous on the body-whorl. Trans. N.Z. Ixst., Vol. L Plate XVII I. Figs. 1, la. — Calliostoma gracilis n. sp. Figs. 2, 2a. — H el incus aucklandicus n. sp. Figs. 3, 3;/. — Dolicholatirus (Pseudolatims) n. sp. Figs. 4, 4a. — Plios kaiparaensis n. sp. Figs. 5, 5a. — PAos spiralis n. sp. Figs. 6, 6a. — Cymbiola nitens n. sp. Face p. 264.] Figs. 7, la. — Cymbiola calcar n. sp. Figs. 8, 8i. — Tunis ornatus n. sp. ornatus Figs. 9, 9a. — Tunis kaiparaensis n. sp. Figs. 10, 10a. — Borsonia (Cordieria) ovalis Figs. 11, 11a. — Crenilabium zelandicum a. Figs. 12, 12a. — C ymbiola masefieldi n. sp. (All figs, x 2\.) n. sp. sp. Trans. X.Z. Insi., Vol. L. Plate XIX. m * ^^d • fy 9 10 m * f f 11 12 13 14 15 16 Fig. 1. — Tellina (Arcopagia) inconspicua n. sp. Fig. 2. — Tellina (Arcopagia) inconspicua 11. sp. ( X 2.) Fig. 3. — Surcula nitens n. sp. Fig. 4. — Corbula nitens n. sp. Fig. 5. — Sarepta aucklandica n. sp. ( X 2.) Fig. 6. — Sarepta aucklandira n. sp. Fig. 7. — Corbula nitens n. sp. Fig. 8. — Ejntonium tricinctum n. sp. Fig. 9. — Mitrella inconspicua n. sp. Fig. 10. — Mangilia axialis n. sp. Fig. 11. — Drillia tenuispiralis n. sp. Fig. 12. — Epitonium tricinctum n. sp. Fig. 13.— Mitrella inconspicua n. sp. Fig. 14. — Mangilia axialis n. sp. Fig. 15. — Surcula nitens n. sp. Fig. 1 6. — Drillia tenuispiralis n. sp. (All figs, except 2 and 5 X 3.) Marshall. — Tertiary Molluscan Fauna of Pahaurangi Point. 265 Several specimens, in good condition. Type in the Wanganui Museum. This species most closely resembles S. costata, but the anterior canal is more bent and the costae less pronounced, though the spiral ribs are more distinct. Coptochetus zelandicus n. sp. (Plate XXII, fig. 13.) Shell of moderate size, 24 mm. by 8 mm., of a fusiform shape, with a - 1 >ire of 5 whorls. Whorls slightly convex in outline and gradually decreasing in size. Body- whorl somewhat incomplete. Aperture narrow and extended somewhat anteriorly into a moderately long canal. Columella smooth and almost straight. Ornamentation : Each whorl has 18 or 19 radial ribs. The ribs are rounded, continuous, and of equal height from suture to suture. The ribs are crossed by about 9 spiral threads of small size on each whorl. Suture with a sharp border on the anterior margin. Body- whorl with similar ornamentation to that of the spire. The radial ribs appear to extend to the end of the anterior canal, though the imperfect condition of the specimen does not show this clearly. One specimen only, in an imperfect state. Type in the Wanganui .Museum. I am indebted to Mr. Suter for suggesting that the specimen should be referred to this genus, though he states that he is not certain that it is correct. The genus Coptochetus appears to be restricted to the Oligocene and Eocene. It occurs in Europe and Australia. Phos kaiparaensis n. sp. (Plate XVIII, figs. 4, 4a.) Shell small and oval, 7 mm. by 5 mm. Spire of 5 whorls, three of which are apparently the protoconch. Aperture less than half the length of the shell, broadly oval but narrowing anteriorly to a very short canal slightly bent backwards. Ornamentation : 10 radial costae on each whorl, broad and rounded but most prominent near the anterior suture. The whorls of the protoconch have no costae. There are a large number of spiral ridges on each whorl, well rounded, and continuous across the costae. On the protoconch the threads are relatively larger and less numerous. On the body-whorl the costae decrease in size anteriorly and end at about two- thirds of its length. The spiral ridges extend to the end of the short siphon. Suture impressed but not bordered. One specimen only, in good condition. Mr. Suter thinks that it is not mature Type in the Wanganui Museum. Phos spiralis n. sp. (Plate XVIII, figs. 5, 5a.) Shell small, oval, 10 mm. by 6 mm. Spire consisting of 5 whorls rapidly decreasing : two of these are the protoconch. Aperture oval, rather less than half the length of the shell. The aperture narrows some- what anteriorly and forms a short canal. There is a slight callosity on the columella, which is a little bent over to the left. Ornamentation : Axial costae 13 in number, broad and low, extending from suture to suture. They are crossed by a number of relatively large spiral ridges. There are 5 of these in the penultimate whorl, and they cross the costae without diminution. Protoconch smooth. Outline of whorls convex, suture im- pressed. The costae on the body-whorl become less prominent towards the anterior end, but the spiral threads are continuous. One specimen only, in a good state of preservation. Mr. Suter thinks that it is not mature. Type in the Wanganui Museum. 266 Transactions. Cymbiola masefieldi n. sp. (Plate XVIII, figs. 12, 12a.) Shell of moderate size, 21 mm. by 8 mm. The type specimen, however, is not quite complete: if it were, the length would probably be 25mm. Shape fusiform. Spire of 5 whorls separated by a deep suture. Each whorl with a convex outline rising steeply from the posterior suture but sloping gently anteriorly. Body - whorl about two - thirds of the total length. Aperture about one-third of the length of the shell, narrowly oval, extended anteriorly into a short canal. Columella without callosity but with two distinct plaits. Ornamentation slight. Two or three narrow spiral grooves on the posterior portion of each whorl. Base with about 12 spiral grooves filling all the space between the base of the aperture and the apex of the canal. Growth-lines are distinct on all the whorls. Three specimens, in rather an imperfect condition. Type in the Wanga- nui Museum. Cymbiola nitens n. sp. (Plate XVIII, figs. 6, 6«.) Shell of moderate size, 26 mm. by 8 mm. Spire of moderate length, consisting of 5 or 6 whorls. Each whorl slightly convex, with a steep slope behind. Body-whorl about two-thirds the length of the shell, aperture about one-third. Aperture narrow, extended anteriorly into a short canal. Columella with no callus but with 2 strong folds of almost equal size. Ornamentation : Surface smooth and polished. A few spiral grooves in each whorl : these are deeper and more pronounced near the upper part of each whorl. Body-whorl with 2 of these grooves near its posterior end, with 13 grooves near its anterior end, where it is prolonged into a short canal. Growth-lines distinct. This species is very closely related to 0. masefieldi, but it has more numerous but less distinct spiral grooves, and the outline of the whorls is less convex. Three specimens only, one of which is in good condition. Type in the Wanganui Museum. Cymbiola calcar n. sp. (Plate XVIII, figs. 7, la.) Shell small, 9 mm. by 4 mm. Shape ovate. Spire rather short, of 7 whorls, rapidly decreasing : three of these constitute the protoconch. Body- whorl distinctly longer than the rest of the shell. Aperture nearly one-half the length of the shell, ovate. Outer lip not preserved ; columella without callosity, but with 2 sharp folds, the posterior of which is sharper than the anterior and more oblique than it. A well-developed but short anterior canal. Whorls slightly convex, steep on the posterior side but gently sloping on the anterior side. All the whorls have narrow spiral grooves. Body-whorl with 6 strong distant narrow ridges on the anterior part. Lines of growth distinct. One specimen only, in good condition. Type in the Wanganui Museum. Mitrella inconspicua n. sp. (Plate XIX, figs. 9, 13.) Shell minute, 4 mm. by 1"5 mm., shortly fusiform. Spire of 6 whorls almost flat in profile. Aperture considerably less than one-half the length of the shell. Outer lip starting at a sharp angle, thick at first, but becoming thin towards the short anterior canal. Columella with 6 distinct spiral lines extending outward over the body-whorl. Protoconch of 3 smooth whorls. Ornamentation : Whorls almost smooth, though with obscure irregular radial lines. Suture impressed. Marshall. — Tertiary Molluscan Fa nun of Pakaurangi Point. 267 One specimen only, in good condition. Type in the Wanganui Museum. Mr. Suter thinks that this species is closely related to M . choava Eeeve, but is distinct from it. Ancilla spinigera n. sp. (Plate XX, figs. 1, la.) Shell of moderate size, 23 mm. by 14 mm., oval in shape, but the spire is extremely short, and is completely covered with a callus from which the protoconch projects as a small spine. Aperture three-quarters the length of the shell. The grooves in the columella are well marked, but towards the base of the columella it becomes extremely callous. Fasciole well marked. The body- whorl has distinct growth-marks, and on the callus there are some indistinct radial mark-. The callus extends forward from the columella over the body-whorl for about one-third of its circum- ference, reaching as far as the fasciole. Three specimens, two of them in good condition. Type in the Wanganui Museum. Ancilla cincta n. sp. (Plate XX, figs. 2, 2a.) Shell of moderate size, 28 mm. by 13 mm. ; form elliptical, the proto- conch projecting as a sharp point. Spire short, and completely covered with callus. Aperture nearly two-thirds the length of the shell. Columella callous, and the callosity extends forward a short distance over the body- whorl. On the callosity which covers the spire a few spiral ridges are rather evident : these apparently indicate the whorls of the spire, which thus seems to consist of 4 whorls. Lines of growth are distinct over that part of the body-whorl that is not covered with callus. One specimen only, in a fair state of preservation. Type in the Wanganui Museum. Surcula latiaxialis n. sp. (Plate XX, figs. 3, 3a.) Shell rather large, 34 mm. by 11 mm. Shape fusiform, with a long spire of 5 whorls, which are strongly convex. Aperture slightly longer than the spire, but oval in shape, though rather prolonged anteriorly. Columella distinctly bulging at the point where the aperture narrows to the anterior canal. Ornamentation : 7 prominent axial costae in each whorl ; these extend to the anterior suture, which bends forward slightly at the points where the axials reach it. Posteriorly the axial sutures stop short of the suture ; anteriorly the sutures are margined by a strong ridge, which is itself marked by extremely fine spiral lines. Whorls marked by numerous fine spiral lines, which traverse the axial costae as well as the other parts of the whorl. The spiral lines are finer and more numerous in the posterior part of the whorl, and are coarsest where they cross the axials. These are crossed by irregular lines of growth, the form of which indicate that the anal sinus was relatively shallow. The outer lip is not sufficiently well preserved to demonstrate that point. This species is rather similar to S. fusiformis Hutton, from which it differs in the smaller number of its broad axial costae, which number 7 in place of 11 ; by the spiral striation of the posterior part of each whorl, and by the bordered and wavy suture. Two specimens only, one of which is nearly complete. Type in the Wanganui Museum. Surcula nitens n. sp. (Plate XIX, figs. 3, 15.) Shell small, fusiform, 8 mm. by 2-5 mm. Spire of 5 convex tapering whorls, half as long again as the aperture. Suture slightly bordered 268 . Transactions. anteriorly. Aperture oval, anal notch rather shallow ; anterior canal of moderate length. Ornamentation : 10 broad and rounded radial costae in each whorl. These costae extend to the anterior but not to the posterior suture. Surface of the shell quite smooth except at the end of the beak, which has 10 feeble spiral lines. Protoconch consists of 3 whorls. The smoothness of the surface distinguishes this species. Two specimens, in good condition. Type in the Wanganui Museum. Surcula ordinaria n. sp. (Plate XX, figs. 4, 4a.) Shell of rather large size, 32 mm. by 8 mm. ; fusiform, with a tapering spire of 6 or 7 whorls. The narrow aperture is half the length of the shell, and is prolonged into a long anterior canal. The outer lip is thin, with a broad shallow anal notch near the suture but separated from it. Inner lip smooth. Protoconch smooth, of 4 whorls. Ornamentation is not con- spicuous. In each whorl the posterior suture is margined with a broad spiral swelling. On this there are fine barely visible spiral striations, which are also to be distinguished on all the posterior part of the whorl as far as the keel. This is well marked, and has about 12 rounded tubercles on each whorl. Anterior to the keel there are about 9 spiral lines, more con- spicuous than those posterior to it. Lines of growth numerous and well marked. Body-whorl with numerous spiral lines, about every fourth of which is larger than the others. Fifteen of these larger lines can be distinguished. Three specimens, two of which are in good condition. Type in the Wanganui Museum. x&~- Turris ornatus n. sp. (Plate XVIII, figs. 8, 8a.) Shell small, fusiform, 18 mm. by 6 mm. Spire of 6 whorls, each with a pronounced keel. Suture impressed. Body-whorl rather more than half the total length, but aperture rather less than half. Aperture oval in form and produced anteriorly into a long canal. Anal notch rather deep. Columella nearly straight and. covered with a thin callus. Ornamentation : A broad keel with about 24 rounded tubercles on each whorl. A second smaller keel posterior to this, and a third near the posterior suture, but the last is quite small : both of these are slightly rough but have no well-defined tubercles. Two slender spiral lines in front of the keel and one on the posterior side. Abundant and prominent growth-lines. Body-whorl with a number of nearly equal spiral ridges in front of the keel, and these are crossed by numerous growth-lines. Two good specimens and other fragments. Type in the Wanganui Museum. Turris kaiparaensis n. sp. (Plate XVIII, figs. 9, 9a.) Shell small, fusiform, 20 mm. by 7 mm. Spire of 7 whorls, strongly keeled. Body-whorl about half the length of the shell. Aperture about one-third, oval, rather obtuse posteriorly but anteriorly produced into a long canal. Columella nearly straight and very slightly callous. Anal notch deep. Ornamentation : A prominent keel with a slight median groove bearing 22 rounded tubercles in each whorl. Eleven thin spiral threads posterior to the keel, the one nearest to the suture being much the largest. Spiral threads crossed by many thin lines of growth. Body-whorl with 3 prominent rather diverging spiral lines anterior to the keel : the middle of these passes through the point where the outer lip joins the shell ; the Marshall. — Tertiary Molluscam Fa nun of Pakaurangi Point. 269 anterior one passes into the aperture. There are many other spiral threads on the body-whorl, every alternate one being relatively small. A very common species at Pakaurangi Point, no fewer than forty specimens being obtained. Type in the Wanganui Museum. Borsonia (Cordieria) ovalis n. sp. (Plate XVIII, figs. 10, 10a.) Shell small, oval, 13 mm. by 9 mm. Spire short, consisting of 4 rapidly diminishing whorls. Outline of whorls slightly convex. Aperture oval, rather less than half the length of the shell. Outer lip thick, inner lip not callous. The columella with 3 distinct folds. Aperture obtuse anteriorly. Ornamentation: Each whorl. with about 15 radial costae slightly raised and continuous from suture to suture : these costae are turned slightly backward. A number of sharp spiral threads, which, however, are inter- rupted, on the costae. Suture impressed and not bordered. On the body-whorl the costae decrease anteriorly, and are not distinct on the base. Many of the spiral threads, however, continue into the aperture. One specimen only, in a good state of preservation. I am indebted to Mr. Suter for placing this specimen generically. Type in the Wanganui Museum. Drillia tenuispiralis n. sp. (Plate XIX, figs. 11, 16.) Shell small, turreted, 12 mm. by 4 mm. ; fusiform in shape, with a taper- ing spire consisting of 7 whorls. Outline of each whorl strongly convex. Aperture rather more than one-quarter the length of the shell, with a short anterior canal and a deep anal slit. Each whorl with 6 prominent radial costae, which extend from the anterior suture for two-thirds of the breadth of the whorl. At this point they terminate abruptly, and leave the posterior portion of the whorl almost smooth. The anterior part of each whorl is marked with numerous extremely fine spiral lines. On the body- whorl the radial costae are far less prominent, and towards the outer lip they are replaced by prominent lines of growth. Spiral threads are con- tinued to the end of the anterior canal. A slight callosity on the columella. Mr. Suter remarks that this species conies nearest to D. costifer Suter. A single specimen, but in excellent condition. Type in the Wanganui Museum. Mangilia axialis n. sp. (Plate XIX, figs. 10, 14.) Shell small, fusiform, 6 mm. by 2*5 mm. Spire consisting of 5 strongly convex whorls. Aperture oval, more than one-third but less than one-half the length of the shell. A very short anterior canal. Outer lip thick. Columella' smooth. Ornamentation : Strong axial ribs to the number of 12 on each whorl : they are rounded and extend from suture to suture, and are bent slightly forward in the lower part, though broader in the middle than elsewhere. A large number of fine spiral lines, which are more pro- minent in the interstices than on the ribs. Body-whorl with the same ornamentation, the axial ribs extending almost to the end of the short canal. Protoconch of 3 perfectly smooth whorls. Rather similar to M. tenuispiralis, but the spiral lines of M. axialis are finer, the axial ribs less pronounced, the body-whorl ribbed, and the form is more slender than in M. tenuispiralis. Three specimens, one in very good condition. Type in the Wanganui Museum. 270 Transactions. Conus (Leptoconus) lyratus n. sp. (Plate XX, figs. 5, 5a.) Shell of moderate size, 28 mm. by 10 mm. Spire short, about one-fifth the length of the body-whorl. Five whorls, each slightly convex in outline. Each whorl rising by a decided step from the anterior suture. Aperture narrow but expanding slightly anteriorly. Ornamentation : Whorls smooth except for numerous distinct lines of growth which extend completely across them. Body- whorl with distinct spiral lirae over its whole surface, though they are more distinct in the anterior than in the posterior portion. Lines of growth on the body-whorl are not numerous and not distinct. A single specimen, in good condition. Type in the Wanganui Museum. Conus convexus n. sp. (Plate XX, figs. 6, 6a.) Shell of moderate size, 27 mm. by 13 mm. Spire conical, about one- sixth the length of the shell, and consisting of 5 whorls. Outline of each whorl convex. Aperture linear, narrow. Ornamentation : Whorls of the spire lyrate with about 10 lirae, which are more pronounced on the anterior than on the posterior part of the whorl. Lines of growth not distinct. Body- whorl has fairly well-marked lines of growth, but it is otherwise smooth except for some 10 spiral lirae near the anterior end. A single specimen, in good condition. Type in the Wanganui Museum. Conus (Lithoconus) abruptus. n. sp. (Plate XX, figs. 7, 7a.) Shell of moderate size, conical, 20 mm. by 11 mm. Spire of 5 whorls, almost flat, and from it the protoconch of 3 whorls projects sharply. Aperture narrow. Columella with a spiral groove near its anterior end. Ornamentation : The whorls of the spire each with about 5 spiral lirae crossed by numerous growth-lines. Suture moderately deep. Body-whorl with numerous but indistinct growth-lines. Eleven distinct spiral lirae near the anterior end. Otherwise the surface is quite smooth. One specimen, in good condition. This subgenus has not previously been recorded from New Zealand. Type in the Wanganui Museum. Crenilabium zelandicum n. sp. (Plate XVIII, figs. 11, 11a.) Shell small, 10 mm. by 3 mm., tapering. Spire evidently short, but only one whorl remains. Aperture more than half the length of the shell, narrow below but rapidly widening in the middle. A short anterior canal. Outline of whorl almost flat. Ornamentation : A series of rounded spiral lines which extend to the anterior end of the shell. Columella with a thin fold. One specimen only, somewhat imperfect. It is, however, certainly rightly placed in this genus, which has not previously been recorded from New Zealand. Type in the Wanganui Museum. Anomia poculifera n. sp. (Plate XXI, figs. 1, la.) Shell of small size : height, 25 mm. ; length, 18 mm. Shape rather obtusely oval. Shell thin and inequilateral, with a nacreous interior. Right valve strongly convex. Anterior end somewhat truncated, posterior end somewhat longer. Foramen moderate, the processes united. Sculpture : 7 large rounded radiating ribs, somewhat bent, and extending from the umbo to the ventral margin. Surface covered with small semilunar cups just in contact with one another and with the convex side nearest the umbo. Muscular impression large. A single specimen of the right valve, in good condition. Type in the Wanganui Museum. Trans. N.Z. Inst., Vol. L. Plate XX. Figs. 1, ]a. — Ancilla spiniyera n. sp. Figs. 5, frt. — Conns {Leptoconus) hjratus Figs. 2, 2a. — Ancilla cincta n. sp. n. sp. Figs. 3, 3a. — Surcula latiaxialis n. sp. Figs. 6, 6a. — Cowms convexus n. sp. Figs. 4, 4-*. — Surcula ordinaria n. sp. Figs. 7, 7a. — Conus{Lithoconus)abruptus (All figs, x 2.) n- SP- i^ace p. 270.] Trans. X.Z. Inst., Vol. L Plate XXI. Figs. 1, la. — Anomia poculifera a. sp. Figs. 2, 2a. — Spcmdyhis aucklandicus n. sp. Figs. 3. 3a. — Mytilus tqrquatus n. sp. Figs. 4, in. — Dosinia tumida n. sp. (All figs, except 5 and 5a X 2.) Figs. 5, fa. — Cardium (Glans) kaiparaensis n. sp. (x 1|.) Figs. 6, 6a. — M acrocallistartculplurata n. sp. Marshall. — Tertiary Molluscan Fauna of Pakaur'angi Point. 271 Sarepta aucklandica n. sp. (Plate XIX, figs. 5, 6.) Shell small and thin : height, 9 mm. ; length, 6 mm. Shape semi- orbieular. Umbo fairly prominent, almost in the middle of the dorsal margin. Ventral margin circular. Dorsal margin descending slowly behind but gently rounded in front. Surface of the shell smooth and almost polished, though faint concentric lines can be distinguished. About 9 small teeth can be distinguished on either side of the umbo, but they commence rather more closely to it on the posterior than on the anterior side. Ligament-pit triangular and directed forward. Not verv common. Only two good valves (both left) were found. 1 am indebted to Mr. Suter for information as to the correct place of this species in classification. Type in the Wanganui Museum. Mytilus torquatus n. sp. (Plate XXI, figs. 3, 3a.) Shell small, elongated, inflated : height, 22 mm. ; length, 14 mm. ; thick- ness, 9 mm. Inflated anteriorly, compressed posteriorly. Slightly winged about the middle. Beak acute, strongly curved anteriorly. Dorsal margin ascending for a short distance, then bent quickly through an angle of 70°, forming a straight line along the anterior margin. Ventral margin gradually rounded, returning with a gradual sweep to the dorsal margin. Surface finely striated. The striae ramify repeatedly along the central line, then extend without further branching to the margin. Striae rounded, very fine on the anterior slope, about as wide as the interstices. They are crossed by very wide concentric undulations and by small cross-threads. Two specimens only, both right valves, in good condition. Closely related to M. huttoni Cossmann = M . striatus Hutton. Spondylus aucklandicus n. sp. (Plate XXI, figs. 2, 2a.) Shell of moderate size, only 20 mm. high and 30 mm. long. Strongly inequilateral with a considerable posterior expansion. Hinge-line straight with a typical provinculum. On the left valve the area is small and almost linear. Umbo not prominent. Crural teeth very large and with 2 or 3 crenulations on the dorsal side. Ligament-pit distinct, with a well- marked ridge on either side. Ornamentation : One or two broad concentric undulations crossed by a number of scaly but not spiny radiating ridges of extremely unequal size. Generally 3 or 4 smaller ribs between the larger ones. The ribs are somewhat irregularly curved, and are continued to the margin, near which they are discernible also on the inner side. On the inner surface, however, they only extend as far as the pallia! line. Two specimens only, one of which is in a very good state of preservation . Type in the Wanganui Museum. No species of this genus has previously been recorded from the Tertiary deposits of New Zealand, but Professor Woods has lately recorded a specimen, too imperfect for description, from the Cretaceous rocks of North Canterbury. There is also a very large specimen of Spondylus in the Auckland Museum which is labelled as coming from Hawke s Bay. Dosinia tumida n. sp. (Plate XXI, figs. 4, 4a.) Shell small, ovato-orbicular : height, 17 mm. ; length, 20 mm. ; thick- ness, 7 mm. Dorsal margin sloping gently posteriorly and developing gradually into the almost circular curve of the ventral margin. Inner surface of the margin delicately crenulated. Umbo fairly prominent and distinctly bent anteriorly. Sculpture a fine concentric striation with strongly incised concentric grooves at intervals. Hinge-plate rather small. 272 Transaction*. Posterior cardinal tooth in the left valve less markedly bihd than in D. greyi Zittel, but well separated from the posterior cardinal tooth. Anterior lateral tooth small, but the posterior lateral large, long, and sharp. A single left valve, in good condition. Type in the Wanganui Museum. This species is closely related to D. greyi Zittel. Cardium (Glans) kaiparaensis n. sp. (Plate XXI, figs. 5, 5a.) Shell small, nearly orbicular : height, 30 mm. ; length, 35 mm. : somewhat inequilateral and ventricose. Umbo pointed well forward and strongly incurved. Anterior end the shorter and regularly rounded. Dorsal margin gently sloping and ventral margin broadly rounded. Sculpture : The surface is coarsely ribbed, some 35 ribs being present. The ribs are narrower than the interstices, sharp and strongly nodulose. Interstices crossed by numerous fine concentric threads, which do not cross the ribs. Margin sharply dentate. Hinge-plate bow-shaped. Left valve with 1 large cardinal tooth, 1 large and long posterior lateral, and 1 short anterior lateral. Right valve : cardinal tooth long and slender ; posterior lateral long, and anterior lateral small. A common species at Pakaurangi Point, but the shells vary greatly in size. Type in the Wanganui Museum. Tellina (Arcopagia) inconspicua n. sp. (Plate XIX, figs. 1, 2.) Shell small, very thin, broadly oval : length, 14 mm. ; height, 8 mm. ; thickness, 4 mm. : slightly compressed, somewhat inequilateral. Beaks rather produced, situated a little behind the middle. Dorsal edge straight, ventral margin strongly rounded. Valves equally convex. Sculpture consisting of numerous fine rather irregular concentric rounded ridges. A large rounded radiating rib on the posterior portion of the right valve. In the right valve the two cardinal teeth are of equal size. The anterior lateral tooth is much nearer to the cardinals and is much larger than the posterior tooth. Not uncommon, but the thin and fragile nature of the shell makes it difficult to obtain good specimens. Type in the Wanganui Museum. Macrocallista sculpturata n. sp. (Plate XXI, figs. 6, 6a.) Shell small, broadly ovate : height, 20 mm. ; width, 25 mm. Dorsal margin arched. Anterior margin at first straight, then arched and rounded. Ventral and posterior margins well rounded. The 3 cardinal teeth are well marked and large. The first anterior lateral is small and obtuse. The second anterior lateral is long and reaches to the margin. The 2 posterior lateral teeth are sharp. Sculpture : A fine general concentric striation is nearly obsolete. On the posterior portion a series of fine wavy striations nearly parallel to the margin. On the anterior portion an angular or V-shaped sculpture can be seen over a portion of the surface. A single right valve in a good state of preservation. Type in the Wanganui Museum. Corbula nitens n. sp. (Plate XIX, figs. 4, 7.) Shell very small : height, 4 mm. ; length, 7 mm. : subtrigonal. Valves not greatly unequal in size, but the right valve is considerably more convex than the left. Umbones of the two valves equal and incurved. Dorsal margin sloping. Anterior end distinctly the shorter, and rounded ; posterior end rather the longer, and rostrate. Ventral margin gently rounded. Sculpture : Both valves with a rounded ridge extending from Trans. N.Z. Inst., Vol. L. Plate XXII. 9 \ k Fig. 1. — Pecten eostato-striatus n. sp. Fig. 2. — Pecten eostato-striatus n. sp. Fig. 3. — Pecten eostato-striatus n. sp. Fig. 4. — Pecten subconvexus n. sp. Fig. 5. — Pecten subconvexus n. sp. Fig. 6. — Pecten subconvexus n. sp. Fig. 7. — Vaginella torpedo n. sp. Face p. 272.] Fig. 8. — Vaginella torpedo n. sp. Fig. 9. — Fusinus corrugatus n. sp. Fig. 10. — Fusinus corrugatus n. sp. Fig. 11. — Siphonalia flexuosa n. sp. Fig. 12. — Siphonalia flexuosa n. sp. Fig. 13. — Coptochetus zAandicus n. sp. (All figs, x 2.) Marshall. — Tertiary Molluscan Fauna of Pakaurangi Point. 273 the umbo to the posterior truncation : this is much sharper in the left valve than in the right. - Near the umbo the right valve is smooth or has very small concentric striae. The concentric lines become more and more pro- nounced as the ventral margin is approached. The sculpture of the left valve is similar but somewhat less pronounced than that of the right. The outer coating of the shell is frequently absent, and then leaves a perfectly smooth and polished inner layer. A common species at Pakaurangi Point. Type in the Wanganui Museum. Pecten costato-striatus n. sp. (Plate XXII, figs. 1, 2, 3.) Shell small, slightly inequilateral, fan-shaped : height, 17 mm. ; breadth, 18 mm. Ears very unequal. Anterior ear large, nearly triangular, but with the outer margin rounded. It bears 7 radiating ribs crossed by a number of transverse bars which are almost spiny. The radiating ribs which are near the hinge-line are much stronger than the others. Posterior ear much stronger, smaller, with 5 ribs less strongly crossed by transverse bars. Eight valve with about 40 rounded radiating ribs, many of which subdivide into 3 each near the ventral margin. Each rib is crossed by a large number of transverse striations : these are so deep as to almost make the ribs appear to be composed of a large number of overlapping plates. Towards the ventral margin these may develop into small spiny processes. Interstices about as wide as the ribs, and crossed by a large number of fine transverse lines. I am much indebted to Mr. Suter for examining this species, which he rightly remarks is closely related to P. burnetii Zittel. This species is perhaps the most abundant of the pectens at Pakaurangi Point. Type in the Wanganui Museum. '■&'■ Pecten subconvexus n. sp. (Plate XXII, figs. 4, 5, 6.) Shell small, fan-shaped : height, 16 mm. ; breadth, 16 mm. : slightly inequilateral. Ventral margin nearly circular. Ears unequal, the anterior distinctly the larger with 6 radiating scaly ribs ; posterior ear relatively small but with the same number of ribs, though they are less scaly and less prominent than those of the anterior rib. The shell has a large number of rounded radiating ribs. Intervening grooves usually much narrower than the ribs, and both the grooves and the ribs are marked by a large number of fine cross-lines. In some valves some 5 large radiating undu- lations can be distinguished. Mr. Suter, who kindly examined these specimens for me, remarks that the species is near to P. convexus Q. & G. This specie's is fairly abundant at Pakaurangi Point. Type in the Wanganui Museum. Including the species described above, the following is now the com- plete list of the species that I have found at Pakaurangi Point. Those marked * are Recent species. Vaginella torpedo n. sp. * Em arg 'inula striatula Q. & G. Solar iella stoliczhai Zittel. Calliostoma gracilis n. sp. Astraea subfimbriata Suter. Turritella semiconcava Suter. Struthiolaria cincta Hutton. Cerithiella fidicula Suter. Crepidula gregaria Sowerby. *Calyptraea maculata Linn. Turbo etheridgei Ten. -Woods (?). *Natica zelandica Q. & G. Polynices gibbosus Hutton. Ampullina suturalis Hutton. *Trivia avellauioides McCoy. Cymatium minimum. Hutton. Epitonium browni Zittel. Epitonium trilineatum n. sp. 274 Transactions. *Crossea labiata Suter. *Phalium qchatinum pyrum Lamk. Galeodea senex Hutton. Galeodea muricata Hector. Galeodea sulcata Hutton. Architectonica n. sp. {(). Heliacus aucMandicus n. sp. Fusinus kaiparaensis Suter. Fusinus morgani Suter. Fusinus corrugatus u. sp. Dolicholatirus (Pseudolatirus) or- natus n. sp. Ptychatractus pukeuriensis Suter. Ptychatractus tenuiliratus Suter. *Siphonalia dilatata Q. & G. Siphonalia flexuosa n. sp. Coptochetus zelandicus n. sp. Cominella carinata Hutton. Phos kaiparaensis n. sp. Phos spiralis n. sp. Alectrion socialis Hutton. *Murex angasi Crosse. *Murex zelandicus Q. & G. Murex zelandicus komiticus Suter. Cymbiola corrugata Hutton. Cymbiola nitens n. sp. Cymbiola masefieldi n. sp. Cymbiola calcar n. sp. *Ancilla australis Sowerby. Ancilla jjapillata Tate. Ancilla spinigera n. sp. Ancilla cincta n. sp. Marginella conica Harris. Marginella harrisi Cossmann. Surcula climacota Suter. Surcula fusiformis Hutton. Surcula latiaxialis n. sp. Surcula nitens n. sp. Surcula or dinar ia n. sp. Leucosyrinx alta transennus Suter. Turris ornatus n. sp. Tunis kaiparaensis n. sp. Drillia awamoaensis Hutton. Drillia imperfecta Suter. Drillia tenuispiralis n. sp. Borsonia (Cordieria) oralis n. sp. Bathytoma haasti Hutton. Bathytoma sulcata excavata Suter. *Mangilia dictyota Hutton. Mangilia axialis n. sp. Conus armoricus Suter. Conus (Leptocomis) lyratus n sp. Conus convexus n. sp. Conus (Lithoconus) abrupt us n. sp. sp. Terebra orycta Suter. Acteon oralis Hutton. *Acteon craticidatus Murdoch and Suter. Crenilabium zelandicum n. Cylichnella enysi Hutton. *Dentalium ecostatum T. W. Kirk. Dentalium pareorense Ikering. Dentalium solidum Hutton. *Cadidus delicatulus Suter. Leda semiteres Hutton. *Leda fastidiosa A. Adams. Sarepta aucklandica n. sp. Anomia poculifera n. sp. *Arca novae-zelandiae Smith. Area subvelata Suter. Glycymeris subglobosus Suter. Cucullaea alta Sowerby. Cucullaea australis Hutton. Mytilus torquatus n. sp. Pecten beethami Hutton. Pecten huttoni Park. Pecten buruetti Zittel. Pecten aldingensis Tate. Pecten costato-striatus n. sp. Pecten subconvexus n. sp. Spondylus aucMandicus n. sp. Lima color at a Hutton. Ostraea wuellerstorfi Zittel. Ostraea nelsoniana Zittel. Ostraea tatei Suter. *Cardita calyculata Linn. Venericardia subintermedia Suter. *Thyasira flexuosa Montague. *Tellina eugenia Suter. *Tellina glabrella Deshayes. Tellina (Areopagia)inconspicua n. sp Crassatellites att&n/uatus Hutton. *Dosinia greyi Zittel. Dosinia tumida n. sp. Macrocallista scidpturata n. sp. Macrocallista assimilis Hutton. Macrocallista pareoraensis Suter. Cytherea chariessa Suter. *Chione meridionalis Sowerby. Paphia curt a Hutton. Cardita (Glans) kaiparaensis n. sp. *Cardium pidchellum Gray. Chama huttoni Hector. Corbula canaliculata Hutton. Corbula kaiparaensis Suter. *Corbula macile>ita Hutton. Corbula nitens n. sp. *Panope zelandica Q. & G. Marshall. — Tertiary MoUuscan Fauna of Pakaurangi Point. 27o This collection from Pakaurangi Point is of rather more than usual interest, as it is the first time that any attempt has been made to identify or describe a Tertiary fauna of such an extensive nature from any northern locality in New Zealand. In the first place, there are several genera that have not previously been recorded from any locality in New Zealand. These are Dolicholatirus, Coptochetus, Crenilabium, Spondylus, Sarepta, and the subgenus Cordieria of Borsonia. On the other hand, Acteou craticulatus, Cadulus delicatulus, and Crossea labiata, all members of the Recent molluscan fauna of New Zealand, have not previously been found in the fossil state. The genera Cymbiola and Surcula are represented by more species than is usual in New Zealand fossil collections from Tertiary localities. The four species of Conus that have been collected give this genus a prominence that it fails to attain in any other collections from New Zealand localities. A more general survey shows that in this collection of 124 species there are as many as forty-five, or 36-3 per cent., which have not been found elsewhere, while 20-3 per cent, are Recent species. Generically and specific- ally, therefore, this fauna is sufficiently distinct from any other that has been recorded. There are, however, no specially archaic types, while there are very many species identical with those that have been found in Tertiary localities in Canterbury and North Otago in those places where full collec- tions have been made. This consideration, and the further fact that nearly 21 per cent, of the species are of Recent occurrence, shows that the age of the Pakaurangi beds is much the same as that of the beds at the North Otago localities of Wharekuri and Otiake — or, in other words, of the Oamaru limestone. In these localities the percentage of Recent species was found by Marshall to be 23*3 and 24 respectively, but in each case only some sixty species were collected. In my previous papers insistence has been laid on the fallacy of relying too implicitly on the criterion of the percentage of the Recent species for the determination of the relative age of the Tertiary strata. The personal equation in connection with the identification of the species, the varying depth of the water, the geographical peculiarities of the station, are all matters that have to be taken into consideration before any comparison of real value can be instituted. In the present case, however, Mr. Suter has been good enough to examine and classify the species from both the Otago localities and from Pakaurangi Point : in consequence the personal equation in this comparison is of little importance. Similarly, the depth of the water in which deposition of the strata took place appears to have been of the same order of magnitude in both cases. Probably it was off-shore water in both cases approaching a depth of 100 fathoms. The geographical features of the different localities may, however, have an important bearing on the question. The localities are nine degrees of latitude apart, and it is obvious that the species in the more northern locality should suggest a warmer climate than those in a locality more than six hundred miles farther south, in water relatively so shallow. There is also a general belief that has been expressed by various authors that the climate of the New Zealand area has become relatively cooler since the early and middle Tertiary times. This opinion is based on the nature of the Tertiary Mollusca as compared with the Recent fauna, on the rela- tively large size of many of the Tertiary species, and of the greater variety of the species. Similar features have been noticed in regard to other animal groups. It is, of course, obvious that a general reduction of the temperature 276 Transactions. within the New Zealand region would be more fatal to the northern species, which, owing to the limited extent of the land, would have no warmer littoral waters to which to migrate, than to the southern species, which would have a large extent of northern coast-line to which they could retire as the climate became cooler. This consideration supports the belief that the small percentage of Recent species in the Pakaurangi beds does not indicate a greater geological age than that of the beds at Wharekuri and of Otiake in North Otago. Actually, as explained in an earlier paper, these Pakaurangi beds succeed the white mudstones conformably, and these mudstones merge into the hydraulic limestones in their lower members. The hydraulic limestone is believed to rest conformably on the greensands, which in certain neighbouring localities contain an Upper Senonian fauna. This fauna includes the ammonoid genera Kossmaticeras, Phylloceras, Lytoceras, and Baculites, as well as the gasteropods Amberleya, Cinulids, and the lamellibranchs Malletia, Panojje, and Inoceramus, amongst several others. It is hoped that this fauna, wThich has been found at Batley and at Bull's Point, both within a few miles of Pakaurangi Point, may be fully described in the next volume of the Transactions. There are at Pahi, some five miles distant, some greensands lying beneath the " hydraulic limestones." In these sediments there are a large number of species of fossil Mollusca, but the shells are in a very poor state of preservation, and no attempt has been made of recent years to classify them. It is, however, the case that the species are mainly, if not entirely, of Cainozoic types, and the horizon is certainly lower than that of the Pakaurangi Point beds. Thus stratigraphically there is not any definite indication of the age of the Pakaurangi beds. There are certainly Upper Senonian beds at about 1,000 ft. below them, and the intervening strata are partly extremely fine mudstones and Globigerina oozes with much diatomaceous and radiolarian matter. Palaeontologically also the exact age of the Pakaurangi beds is not precisely indicated. The percentage of Recent species does not give a satisfactory basis for a comparison with European horizons. The isolation of New Zealand and the relatively rare arrival of species from outside the New Zealand area make it probable that species would survive for a much longer time here than on coast-lines where there was more competition from newly arrived species. It is probable that a fauna in New Zealand with 20 per cent, of Recent species would have a much greater antiquity than a fauna with a similar percentage of Recent species in Europe or America. The actual genera that have, been collected do not appear to indicate any precise Tertiary age. Exilia, Gilbertia, and other genera from the lowest Tertiary beds of the South Island have not been collected here. Fulgoraria has not been found, and Chione is poorly represented. But such facts appear to depend upon station rather than age. Relative strati- graphical position with respect to beds deposited in water of similar depth in other parts of New Zealand would suggest an age rather younger than that of Wharekuri and Otiake, and such a position would generally agree with the palaeontological evidence . On the whole, I am inclined to correlate the beds with those of All Day Bay — that is, next above the Oamaru limestone. As the work of collecting, classifying, and describing the Tertiary Mollusca gradually proceeds the number of species becomes much larger, and the fact emerges that there have been very few generic additions to Marshall. — Tertiary MoUuscan Fauna of Pakaurangi Point. 277 our fauna during Tertiary times. On the other hand, it is clear that many genera have become extinct. It is also the case that many of the genera that were in earlier times well represented have but few species in the present fauna. Those that have become extinct include Cymbiola, Niso, Cypraea, Trivia, Conus, Latirus, Erato, Cerithium, Cardium, Exilia, Cucullaea. More generally it may be said that of the 205 genera mentioned in Mr. Suter's Hand-list of New Zealand Tertiary Mollusca (1915) some forty-eight are now extinct. This statement, however, does not give a com- plete idea of the magnitude of the change that has taken place. Many of the genera that in Tertiary times contained a large number of species are now reduced to a very small number. Of these, Epitonium, Surcula, Tunis, Siphonalia, Struthiolaria, Mangilia, Pecten, and Polinices are the most prominent examples. In this comparison the purely littoral fauna cannot be properly con- sidered, as remains of such organisms are so seldom preserved. No one Tertiary horizon which has had its Mollusca properly collected and described shows any notable introduction of species or genera which are absent from lower horizons. Such facts go far to support the idea of a continuous isola- tion of New Zealand throughout Tertiary times — a contention that has been previously urged by the author on purely stratigraphical grounds. This position has lately been supported by Thomson and Morgan, though stated in a different manner : " Each Tertiary fauna seems to merge gradually into the succeeding one."* Mr. Suter also has written to me as follows : " There is no doubt that our molluscan fauna has greatly decreased, and also that the Tertiary forms gradually merge into one another." These statements appear to me to afford the strongest support from the palaeontological standpoint to the view so frequently urged by me that there is no important break in the succession of Tertiary sediments in New Zealand. In the absence of satisfactory palaeontological material in the past this view has been based on stratigraphical material, and it is satisfactory to note that as the palaeontological material gradually accu- mulates its verity is placed practically beyond doubt. jf^F" It is to be hoped that a complete comparison may be possible ere long between our Tertiary faunas and those of Australia, South America, and North America. In the meantime one can only emphasize the well-known fact that our Tertiary fauna closely resembles that of South America, wheie the species of Turritella, Malletia, Struthiolaria, Epitonium, and Polinices are evidently extremely closely related to ours. Again, the occurrence of the genera Perissolax and Heteroterma in the Wangaloa beds shows a rather unexpected relationship between our earliest Tertiary beds and those of the Tejon and Martinez districts in California. In New Zealand I have frequently stated that there does not appear to be any stratigraphical discordance between the Upper Cretaceous (Senonian) and the Tertiary horizons. In all known cases, however, deep- sea beds of Globigerina or diatomaceous or radiolarian ooze intervene between the Senonian and Tertiary horizons. In South America Wilckens, as previously pointed out, has insisted on an important break between the Senonian and the Miocene. Other authorities on the South American stratigraphy hold very different opinions. The latest that I have seen is that of von Ihering, who maintains emphatically that there is no break between the Cretaceous and Tertiary : " Uberblicken wir die von uns * Preface to Palaeontolocjiral Bulletin No. 5, 191' 278 Transactions. gewonnenen Ergebnisse, so muss jede unbefangene Diskussion die Tatsache anerkennen : dass die marinen Ablagerungen der oberen Kreide von Patagonien eine starke, successive Abnahme von mesozoischen Charakter- formen aufweisen, dass aber andererseits diese letzteren sick zum Teil erhalten, dass mithin die Elemente der Kreidefauna teils unverandert, teils modifiziert in die patagonische Formation iibertreten und dass keine Dis- cordanz zwischen der Kreide und den Ablagerungen der patagonischen Formation besteht."* So far as New Zealand is concerned, then, it appears to be probable that at the close of Cretaceous times a great movement of epeirogenic depression took place. The land area was reduced to the dimensions of a few small islands. Over much of the present land area deep-sea oozes were deposited for a great lapse of time. Marginal deposits were restricted and small. When elevation again commenced the Upper Cretaceous fauna had been replaced by one of Tertiary characteristics. Art. XXVIII. -- Notes on the Geology of the Tubuai Islands and of Pitcairn. By P. Marshall, M.A., D.Sc. [Read before the Wanganui Philosophical Society, 19th December, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 24th June, 1918.] The scattered islands which constitute the Tubuai Group are situated near 23° south latitude and 150° west longitude. Little geological infor- mation has been published about them except in regard to their general configuration and the nature of the coral reefs by which they are encircled. A visit has lately been made to the group by Professor J. Macmillan Brown in connection with his anthropological studies, and he has been good enough to give me chips from implements that he obtained from Tubuai and Rapa. In addition, the Chief Magistrate of Pitcairn sent me several specimens from that island. I have previously published a note on rock- specimens from Rurutu Island, another member of the Tubuai Group. f Stone Axe, Tubuai Island. — A dense black rock in hand-specimens. In section the structure is dominated by an abundance of small laths of feldspar with the extinction angle of labradorite. There are a few large crystals of olivine much serpentinized. There is also a little olivine in the oroundmass. Augite is very plentiful in the groundmass in small colourless trains. Magnetite very abundant. The rock must be classed as a dense, rather acid basalt. Stone Axe, Rapa Island. — In hand-specimens a dark fine-grained rock without any crystals that can be distinguished macroscopically. In section fine laths of feldspar are very abundant. They appear to be an acid labradorite or andesine. Augite is very plentiful, but the grains seldom have any crystalline outline, and they are quite colourless. A little olivine is present in very irregular-shaped grains. Magnetite is very plentiful in crystals up to 0-2 cm. in diameter. A little apatite can be distinguished. This rock is also an acid feldspathic basalt, and, like the specimen from Tubuai, it has an unusual quantity of magnetite * Von Iheeing, Revista do Museu Paulisia, vol. I, Fasc. 3, p. 130 Sao Paulo, 1914. f Trans. N.Z. Inst., vol. 46, p. 283, 1914. Marshall. — Geology of Tubuai Islands and Pitcairn. 279 Poe Pounder, from Rapa Island. — In hand-specimens a coarse rock in which feldspar, augite, and olivine can be easily distinguished. In section the feldspar is found to have occasionally a large angle of extinction — as much as 40°- — and thus is a basic type of labradorite. The great majority of the crystals, however, have very narrow lamellae, and extinguish at angles below 20°. The species apparently varies from andesine to basic labradorite, which is confirmed by the low index of refraction, xiugite is present in large ophitic plates with the pleochroism that is so common in the titaniferou* varieties. Olivine is present in large irregular grains slightly serpentinized, and it is often associated with minute flakes of brown mica. Iron-ore is abundant. It is mainly ilmenite, as shown by the shape of the crystals and by the frequent border of leucoxene. There is much apatite, especi- ally as inclusions in the plates of augite. I have lately received from Mr. G. R. B. Christian, the Chief Magistrate of Pitcairn, a box of rock-specimens from that remote spot. He states that the specimens sent represent the various kinds of rock that are to be found on the island so far as can be judged by external appearance. My only previous reference to rocks of this island is a statement that a specimen given to me by Mr. G. W. Card was a glassy hypersthene andesite.* The rock-specimens that I have now received cause me to correct the previous classification. I now recognize the rock as a glassy basalt. In the specimen previously examined only one small crystal could be seen. It was thought to be hypersthene, but subsequent specimens now show that it was olivine stained slightly with iron oxide. The more numerous specimens that I now have are all fine basalts, many of which are glassy. The feldspar is an acid labradorite. Olivine, usually in idiomorphic crystals, is usually more plentiful than the colourless augite, which is always granular. The fineness and frequently glassy nature of the rocks suggest that they have a submarine origin. So far as these rock-specimens are concerned, they indicate that on several of the islands of the Tubuai Group a similar rock type occurs. Tubuai, Rapa, Rurutu, and Pitcairn at least have highly feldspathic basalts. In general all of the rock-specimens that I have examined are so similar that they all might have occurred on the same island. The specimens from Tubuai and Rapa are types that have been selected by the natives for the manufacture of weapons, and hence they may possibly be unusual types on the islands, selected because of their special fineness or toughness. The specimens from Rurutu and Pitcairn, however, appear to be typical of the rock occurrences on those islands. Generally it may be said that the rocks of the Tubuai Group appear to be less basic than those of Tahiti and the Cook Islands, and the specimens so far examined show none of the alkaline characters found in many of the rocks from those groups. * Handbuch der regionalen Geologie, Bd. vii, Abt. 2, p. 14, 1912. Michel Levy (Examination petrographique de quelques roehes volcaniques des iles Tuamotu et de l'ile Pitcairn, C. R. Acad. Sci. de Paris, cxli, p. 895-97, 1905) writes as follows: '"En resume il existe a Pitcairn et a Mangareva deux series de roehes basaltiques : une plus acide de basaltes andesitiques passant a des andesites a olivine et a des tachylites (Pitcairn): une autre plus basique composee de basaltes labradoriques quelquefois tres augitique d'autrefois tres riche en olivine du premier temps : cette derniere parait etre la plus frequente. II faut voter en outre l'existence a File Pitcairn de ponces tracbitiques presque entierement vitreuses et par suite peu interessantes au pointe de vue niine- ralogique." The more basic type mentioned by Michel Levy was not represented in my specimens. 280 Transactions. Art. XXIX.— A Note on East Coast Earthquakes (N.Z.), 1914-17. By George Hogben, C.M.G., M.A., F.G.S. [Bead before the Wellington Philosophical Society, 12th December, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 24th June, 1918.] Between February, 1914, and November, 1917, about thirty earthquakes (not counting shocks of intensity I or II, Rossi-Forel) were recorded at places on or near the east coast of New Zealand. The chief of these were the earthquakes of 6th-7th October, 1914; 28th October, 1914; 22nd November, 1914 ; and 5th-6th August, 1917. All the shocks came from a region to which in a former paper* I have referred the earthquakes of 9th August, 1904; 9th March, 1890; and 17th February, 1863. The most marked effects of the first three earthquakes (October and November, 1914) appear to have been noted at Tokomaru and other places a little to the south and south-west of East Cape ; but they were sharply felt from Timaru and Greymouth to Auckland. Their intensity was suffi- cient to throw down chimneys in the Tokomaru district, and to stop some clocks in Wellington and other places. The movements originating the vibrations appear to have taken place in each of these cases beneath the sea-bed, probably both at the north- east and south-west ends of the three lines Aa, Bb, Cc, beginning at the north-east point, A, B, or C, and ending at the south-west point, a, b, or c ; suggesting the existence of three fault-planes whose position is shown by the lines on the map. These conclusions rest on the instrumental records from Wellington and Christchurch (Milne seismographs), and from Apia, Riverview (Sydney), and Batavia (Wiechert instruments), and a large number of memoranda from telegraph officers in New Zealand, forwarded to me by the courtesy of the New Zealand Post and Telegraph Depart- ment— which it would take too long to discuss here. (It is quite possible that better records would have made the three lines Aa, Bb, and Cc coincide.) A fact worth noting is that the Milne seismograms of the 6th October at Christchurch and Wellington both showed a considerable tilt of the ground down on the eastern side (7 mm. at Wellington, 5-4 mm. at Christ- church, or 2-28 and T76 seconds of arc respectively). This might have been attributed to instrumental causes were it not that a Milne-Ewing duplex pendulum at Wellington, set up on an independent column about 9 ft. from the column on which the Milne seismograph was placed, showed a tilt of corresponding amount nearly towards the south-east. (The needle of the duplex pendulum is, of course, free to move in any direction horizontally, whereas the Milne seismograph records only the E.-W. com- ponent of the motion.) The earthquake of the 5th-6th August, 1917, was most severely felt in the district between Masterton and Castle Point, especially at the former placef — probably because of the alluvial character of the ground on which the town is built. The epicentral area is near F, in lat. 42° 41' S., long. 178° 12' E., which is not far from the origin of the earthquake of * G. Hogben, Notes on the East Coast Earthquake of 9th August, 1904, Trans. N.Z. Inst, vol. 37, pp. 421-24, 1905. f Probably the intensity at Masterton may be described as between VII and VIII on the Rossi-Forel scale. Hogbeiw — East Coast Earthquakes, 191^-/7. 281 8th August, 1904. A day later (6th— 7th August, 1917) a sharp shock, though not so severe, was felt in the region from Gisborne to the East Cape, evidently from the east or east-south-east. It is quite possible that the latter was from the north-east end of a fault-line of which F marks the south-west end. F is about 185 miles from Wellington, and 285 miles from Christehurch. Earthquake origins east of New Zealand. The times relied upon for the determination of F were those of the first phase ("preliminary tremors") at Apia, Samoa, 15h. 56m. 27s. (Wiechert) ; Riverview, Sydney, 15h. 55 m. lis. (Wiechert); Christehurch, N.Z., 15 h. 51m. 24 s. (Milne); Wellington, N.Z., 15h. 51 m. 6 s. These, with a velocity of propagation of 9-17km. sec, show the time at the origin to have been loh. 50m. 34s., G.M.C.T., 5th August, 1917 (3h. 20 m. 34 s., N.Z.M.T., 6th August). The respective distances of the four places named from F are : Apia, 3,235 km. (chord) ; Riverview, 2,538 km. (chord) ; Christehurch, 456 km. ; Wellington, 296 km. The times and other observations forwarded from New Zealand telegraph -offices, while less exact, afforded a general confirmation of the residt obtained from the instru- mental observations. 282 Transactions. Art. XXX. — -Further Notes on New Zealand Bird-song : Kapiti Island. By Johannes C. Andersen. [Read before the Wellington Philosophical Society, 24th October, 1917 ; received by Editors, 31st December, 1917 ; issued separately, 24th June, 1918.] The figures accompanying this article contain the new notes observed since publication of the paper in the Transactions of 1917.* As before, for con- venience of reference, the variations in the notes of each species of bird have been numbered consecutively from (1) onwards, the earlier numbers appearing in Trans. N.Z. Inst., vol. 41, p. 422 ; vol. 43, p. 656 ; vol. 45, p. 387 ; vol. 47, p. 593 ; vol. 49, p. 519. Reference is at times made to these earlier-numbered variations. As practically the whole of the notes were recorded on Kapiti, the island bird sanctuary in Cook Strait, it has been thought advisable to prefix a list of the birds occurring on the island, and seen or heard by me : — Native Birds. Pied fantail (piwakawaka), Rhipidura flabellifcra. *Grey warbler (riroriro), Pseudogerygone igata. White-breasted tit (miromiro), Petroeca toitoi. North Island robin (toutouwai), Miro australis. Whitehead (pokotea), Certhiparus cdbicapillus. Ground-lark (pihoihoi), Anihus novae-zealandiae. *Blight-bird (tauhou), Zosterops caeridescens. Tui, Prosthemadera novae-zealandiae. Bell-bird (korimako), Anthornis melanura. Rifleman (titipounamu), Acanthidositta chloris. *Shining cuckoo (pipiwharauroa), Chalcococcyx lucidus. Long-tailed cuckoo (koekoea), Urodynamis taitensis. Kingfisher (kotare), Halcyon vagans. Pigeon (kukupa), Hemiphaga novae-zealandiae. Kaka, Nestor meridionalis. Red-fronted parrakeet (kakariki), Cyanorhamphus novae-zealandiae. f Antipodes Island parrakeet, Cyanorhamphus unicolor. Morepork (ruru), Ninox novae-zealandiae. Woodhen (weka), Ocydromus sp. fKiwi, Apteryx sp. Blue heron (matuku), Demiegretta sacra. Blue petrel, Halobaena caerulea. Mutton-bird (titi), Oestrelata sp. Gannet (takapu), Sulci serrator. Tern (tara), Sterna sp. (lull (karoro), Larus sp. Introduced Birds. Song-thrush, Turdus musicus. Skylark, Alauda arvensis. Goldfinch, Carduelis elegans. Starling, Sturnus vulgaris. Californian quail, Callipepla califomica. * Trans. N.Z. Inst., vol. 49, pp. .",19-30. Axdersex. — -New Zealand Bird-song. 283 The birds marked * I neither saw nor heard, but I was assured by the caretaker, Mr. J. L. Bennett, to whom I am deeply indebted for consider- ation shown to me whilst on the island, and by Mr. Webber, who resides at the north end of the island, that they are plentiful at times. The two marked f have been introduced, and appear to have established themselves. A longer residence on the island — I was there three weeks — would probably show a large increase in the number of sea-birds ; and the lagoon in the north is visited by ducks, but I saw none whilst there. I saw no live thrush, but found one dead and heard one sing. Goldfinches suddenly appeared, in flocks. Skylarks were there in numbers, and starlings also. On the evening of the 2nd January, 1917, lying on the hillside, my attention was attracted by a moving cloud above Evans Islet* — a small islet off the coast of Kapiti, and lying between it and the mainland. The cloud vanished, and formed, and vanished, like a cloud high in the blue sky of summer, only with swifter transitions. It was a flight of starlings, many hundreds in number, and the cloud formed by the crowded birds appeared and dis- appeared according as they presented an edge or full body as they flew. The unanimity of movement must have been perfect to cause the regular melting and reappearing of the cloud. The birds gather from many quarters on the mainland, and every evening fly in thousands to Evans Islet, passing the night there, and leaving again, flock by flock, in the morning. A similar habit is observed in Britain, but I have seen no note of such nightly haunt, or starlingery, being divided by the sea from their daily resort. Evans Islet is over two miles from the mainland, and is uninhabited and unoccupied. There is another starlingery on the main- land in a plantation of blue-gums close to Paraparaumu, between it and the sea ; and at sunset there is a great clamour of twittering before the birds settle down for the night. I am told that the birds visit Evans Islet nightly during the breeding season also, but not in such great numbers. I was surprised to see not a single sparrow ; but it is quite possible that this bird, and the other finches, may pay occasional visits : they have, indeed, been reported there at various times. Fantail. I did not see a great number of fantails at Kapiti, but all that I did see were pied. Their song was generally the common whistling song, (15) and (15a), heard about Wellington. The notes of (20) were heard on the gva etffc EE JJrrrmtHt: Wf /ip f-e fee fee fee hp / [^"lSU0 ";: jjflwi IpflWUPifflllrfilVf (L ft#£ »iuu$tf o* e*£ cA o» cA #: i? c 1 1 < ^i" jj»i5»^ tu Au Au Au Au-w«e Sv* A/ct /-/It /■"* - 3*ra z5> I 7balf£iz2 /2< /w A« Aa-ivtecr — — — ■» g~g » . fat ^ ^ "3E y 1/ 1/ k -k-JL /■*/ cutar fvo cAee ft>o £= V / % I (iJ P-zt&P » 55 5 frfr*1^ fr-=-9- 2t=S — * p y^^^ly^fl m m a £ /■/// a /•/ //'// r<^ <^^ .»•«•«><■ *;> < ;^ff r g i h* Bfcfrft *$>&%%'T /zbr. s (33% t-t fr^JJ |»f FP **■ WOrJrJrJ (fe aJ: i £ 2tf f= wS Z8™ - »> • » B-* jyyeesetoo ^^ jeeseejeeeoi opening of " Scenes that are Brightest. '" This led me to hark back in memory to see if I could recollect other bird-phrases that recalled human melodies, but only one came to mind, a phrase by a bell-bird — B flat. B flat, E flat, G, B flat. E flat, B flat, G— which, with the addition of E flat, F, is the second line of " Mill May " : " The bob-o'-link sings on the tree." So far from its being remarkable that bird-phrases should some- times be the same as human melodies, it is to me remarkable that they are not more often the same. 10— Trans 290 Transactions. The notes of (94), heard only occasionally, are reminiscent of calls in the South. The opening sounds, at three quavers a second, were like the sound of a bell through the horn of a gramophone ; they were followed by the common call at a higher pitch. In (95), again, the notes of the chord are sounded. It was sung once only, after flight, and after a second flight the variation (95a). The notes were full flute notes, with regular vocaliza- tion, aw in the low notes, e of " net " in the medium, and ee of " sweet *' t W 4 ^/\ f\ i\ /| _ f\ /[ /] _ /) /| 1 /) /| /= ()N idiWTUt ^7 J 7 J 7*7^7 J 7 4JV47 4y °* 7 «'?7 •? f ? j* f y f ^ f if ?,r f 7 f i f; f 7 g *T hsfohi^ttttt^ift ^ ,?'<»- - ^ 5 ^/^ //|, ':-p~n7 ■*f F* P3 g ' F / |g ^ — *1 — *1 — (• j7y J7 J«EpE ^ ^=* ■7/7 ^y^L jK -^ 1 i? ■ m jzp fe» <**§g gg j atierre ofars j** -, #***- C3?;: ^Ka , ^nr yr //■« //'«■ Aooee-oo a-—- S"* -, frlg> PPPP =f=f=f <• — ^ t^~* ^ I //i^/zift* £/u /ye* yyt'r or rtz/z* >; .7 "^ *-*"• f- ^/S^at >"Tivp /j»y: 8**--- m -*-? 5* /*-M*?zf % <^3 /■/ogJc sweeter //ocfr streeter W& bell-like triplet vocalized hoo-ee-oo. The £m< is very commonly used by the bell-bird, but in (33) it is not apparently slurred, the whole phrase being a vocalized whistle, eight or ten semiquavers a second. The phrase (34), taking two seconds, was repeated many times in succession in an obscure ruinous vale, producing a strange, melancholy feeling. Like many bell- bird phrases, this is in perfect time. 294 Transactions. The whisper-song of the bell-bird appears to be more definite than that of the tui. I took (35) to be one of the tui's bubbling whisper-songs until I actually saw a bell-bird singing a similar theme. It was sung very softly, with curious interjections separating the phrases, about five quavers a second. Often the tlank, or other interjection, only is heard, when it may be known that a whisper-song is in progress, and snatches may be heard on a nearer approach. Similar in character was (37), the phrases being again separated by one of the expletives so liked by the tui. These songs are sung for two or three minutes at a time, are more clear than the tui's, and appear more under the control of the bird. On the theme of (38) was built a long whisper-song, and this song is one of the best examples of art in bird-song that I have heard. It was perfectly regular in time, and each varied phrase was introduced by an expletive. The first part was many times repeated, at times as in the second part, and in several other forms. The notes were mellow, occasionally swelling to a bell sound. At a distance of 20 ft. nothing could be heard but the kwak. at regular intervals of about two seconds. When at half that distance the song was barely audible ; yet, soft as it was, there was a perceptible swell and dying-away in intensity. The song was sung at dusk, and after continuing for two or three minutes stopped abruptly on my attempting to approach up the slope to hear more clearly. Another bird sat in sight close above me singing the short phrase of (39) — partly a whisper-song, the tlock being clear and bell-like. The song (40) suddenly came from close beside me, followed after a moment by the common call. Kara. Noisy as the kaka usually is, the female has a crooning song at breeding- time — a soft, gentle song, quite different from the usual raucous cry. I saw several kaka at Kapiti, but they were quiet : the cry heard was kree-ah, as in (1), taking a little over a second, or kee-aw-w-w-w, as in (1a). the long aw being broken as if by momentary stoppages of the breath, The vocalization was somewhat similar to the cry of the kea, but the sound was fuller and broader. In a secluded valley I saw two kaka sitting on a branch, one a little below the other. The lower bird seemed coaxing the upper with a continual ke ke ke ke as in (2), repeated three notes a second, at intervals of two or three seconds, leaning up towards it, shivering its body and spreading it tail at each repetition. This went on for several (0- 1^ kree-aU D gy~ 1 / * J J *% -+-L 1 M ■ X ■ 1 minutes, when the upper bird, thitherto quite unconcerned and inattentive, seized the lower by the upper bill, apparently, and shook it. The shaking, however, would appear to be due to the act of regurgitation ; the bird was feeding the young one, which waved its wings and sometimes "whined" a little during the shaking. The food was evidently passed into the mouth of the young bird at the end of each quivering. The process was gone through four or five times, the old bird running away each time, or flying to a short distance, and sitting apart for a minute or so. Both birds, when apart, scraped the sides of their beak on the branch, the young one also Andersen. — New Zealand Bird-song . 295 opening and shutting its beak and working its throat as if swallowing, but never moving from its place. After a time the old bird flew off, and the young one seemed instinctively to know it was for good, as it shuffled off along the branch and was hidden in the foliage. Parrakeet. The chuckling cry (3), uttered when resting or during Might, was varied as in (6), six to eight semi cpia vers a second. The do be quick of (5), Banks Peninsula, in 1912, was pretty quick, on one note, at Kapiti, (7), and on one day the sound was distinctly pretty dick, the " d " uttered as by one slightly tongue-tied. Buller makes a good deal of a bird, kept on a railway-station, having been taught to say " Be quick " ; but there is & i } »<*- WXM 4z* m 9- (*ii Au fu fu He fu fit f-u fu fu fu m i /oreff/ aftic/r little need for teaching, as this is the vocalization of some of the natural wild notes. None but red-fronted parrakeets were seen, though on one day an exceptionally large bird, bright green from a back view, and seeming nearly as large as a kaka, flew silently from me up a short glade ; and as I passed the caretaker's house he remarked that he had seen two exception- ally large parrakeets. These would be the Antipodes Island birds liberated at Kapiti by Dr. Cockayne at the end of 1907, or progeny from them. Weka. In only one pair of wekas could I detect any essential difference between the cry of the male and the female. In this pair the cries were as in (12) : the female's was a little higher in pitch, was on one note, and - CMar/fiJ (flf/ncr '"%>*> J 3 V HI 1 [7 J J . (reo-ee Aroo-ee fee e sounded shriller. When calling, the male stood erect, with bill and neck stretched upwards, the bill open as the cry pulsed up through the pipe. The deep mmb of the male often sounded at the same time as the call. 296 Transaction s. Art. XXXI.-- Notes on Eels and Eel-weirs (Tuna and Pa-tuna). By T. W. Downes, Wanganui. [Bead before the Wanganui Philosophical Society, 17th December. 1917; received by Editors. 31st December, 1017 ; issued separately, 24th June. 19ls.\ Plates XXI II- XXXIV. Introduction. In commenting on the annual report of the Wellington Acclimatization Society the London Field says, ' Various things in the report make it clear that the big eels for which the country has always been famous continue to trouble the fisheries. The New Zealand eel is a mysterious creature, as to which one would like more information. He reaches an immense weight, and has been credited with being dangerous even to human beings when they are bathing. A monograph of his life-history and habits would be very interesting." I much regret that I have been unable to find any descriptive matter in connection with our native eels, but in the new edition of Williams's Maori Dictionanj (1917), under the heading " Tuna." the following note is given : " This is the generic name for eel. Nearly a hundred distinctive names are recorded,* many, of course, being synonyms for varieties of the three species observed in New Zealand waters." Five species of fresh- water eels (in addition to the marine conger) are listed by Hutton in his Index,f but no varieties are there recorded. Certainly there appear to be a good many. On the west coast of the North Island, the only district in New Zealand with which I am thoroughly familial', the eel, or tuna as it is called by the Maori, has ever been conspicuous upon the native bill of fare. Indeed, often for months at a time, owing to the fact that they could keep the fish alive, and also as they were able to preserve it by sun-drying, it was their only animal food ; consequently a, large part of the time of the people was formerly spent in the manufacture oihinaki (eel-baskets), pa-tuna (eel-weirs), and other implements used in connection with the fishery. In olden days the pa-tuna was an elaborate as well as an exceedingly strong piece of work, often adorned by carvings, and always made to stand years of flood-timber buffeting ; occasionally it required repairing, but it was never quite destroyed. To-day on several of the upper Whanganui River rapids there are the remains of old pa-tuna, though the huts of the adjoining villages have long since been obliterated by time. I have heard that the Waikato River, with its tributaries, was the most celebrated in New Zealand for its fa-tuna and the quantities of eels found there, right away from the mouth up to the Huka Falls, near Lake Taupo, above which none are found. The Manga-tawhiri, the Maramarua, the * ! am informed by a correspondent that about 110 eel-names are on record, most of which are to be found in the 5th edition of Williams's Maori Dictionary (1917). f F. W. Hutton, Index Faunae Novae Zealandiae, London. 1904. Downbs. — Eels • ^^s»f* >. ^9 Making a po/ia, Waitotara. Trans. X.Z. Inst., Vol. L. Plate XXV '%»wj%m Fig. 1. — Pa-tuna, or eel-weir, at Kauwae-roa, Whanganui River, looking down-stream. £ .^JEMJ £~ -. «__ , : .' i_.,L * f f A. l^-AuMito^^fi Fig. 2. — Pa-tuna at Kauwae-roa, Whanganui River, looking up-stream. The right-angle return posts, or wings, have been carried away. Trans. X.Z. Inst.. Vol. L. Plate XXVI. a eg 03 erf as H c a. Downbs. — Eels and Eel-wetrs. 311 After getting all the poles, timbers, and lashings together, it takes from four to six men at least seven days' hard work to construct the simplest form of this pa-tuna. The hardwood stakes of kopuka* are, as a rule, about 4 in. in diameter, and they are driven into the heavy shingle from 2 ft. to 2ft. Gin. with a sort of wooden maul, called a ta. The weir is. as a rule, from 50 ft. to 60 ft. long and about 20 ft. wide, and the work is commenced at the crest of the rapid and continued down- stream. After a number of poles have been driven in, two horizontal timbers are lashed on, one below the other, after which more stakes are driven, it being easier to keep in line with guiding-timbers on top. A long and very heavy totara log, from 12 in. to 18 in. in dia- meter, is then lashed to the stakes at about low-water level, and further held in position by another row of stakes driven at an angle, the top of the stake finishing flush with the inside of the fence (fig. 6). The last post down-stream is clear of the heavy log, and only held by the top horizontal timber, so as not to interfere with the poha sliding up and down. This will be seen in the picture of the fa-tuna on Te Aute-mutu Rapid (see Plate XXVI). Considerable judgment was required in setting the fences at the proper angle against the current, and because of care in this matter, combined with good workmanship and position, some pa-tuna took more fish than others. The angle of fences was of the utmost importance, and alwaj^s they ran into the current to a greater or less degree according to the arrangement of the stakes. If parallel with the current, or nearly so, few fish were intercepted, and if at too great an angle the eels escaped through the fence. In a close arrangement of stakes, as the pa-tuna at Kauwae-roa (Plate XXV, figs. 1 and 2) a greater angle' is given than in the pa at Te Aute-mutu (Plate XXVI), where the stakes are wider apart. The double fence was only for the purpose of intercepting more fish. A bad architect superintending the construction of a pa-tuna was the object of much derision, and his failure was known throughout the district. An unsuccessful pa was always pulled down. It is said that when eels travel up-stream they usually take the deepest and darkest water, taking advantage of every help, while lampreys keep close to the edge, especially in swift water. The log with its double row of stakes causes a sort of backwater right up the full length of the weir, and provides an easy passage for the wily tuna, which he is not slow to take advantage of. At the top of the p Auna a sloping rounded log, care- fully smoothed, is fixed so as to turn the eels and cause them to be thrown back by the current, which carries them down into the poha before they regain shelter. At the foot of the weir two posts are driven in about 5 ft. away from the fences, one on either side, facing each other, and strongly braced to the main structure, their object being to hold the poha frame. Fig. 6. — Section of large pa -tuna. * I believe the name kopuka is peculiar to the Whangamii River natives, the names kanuka and maru being used for the wood (Leptospermum ericoules) in other places. 312 Transactions . Usually there are sliding logs that work between these posts and the fences, held by the force of water, and also a rope that lifts or lowers them, together with the poha frame of the inverted Y pattern (see later), which is fixed to the hinaki in the manner before described (see fig. 7). These angles, being right across the current, are soon broken by driftwood, and. as a rule, have to be renewed or repaired annually. All the lashings used in the construction of the pa are of aha or kareao vines : no pegs or nails are ever used even in modern times. Usually the fences are lowest at the top of a rapid, gradually rising as they go down-stream. FlG. 7. — Attachment of the poha. 1, angle brace ; 2. sliding timber used to raise and lower the poha- : 3, hinaki ; 4. ropes of twisted kareao. The names of the parts of the pa-tuna are as follows : The stakes are called pou ; the top horizontal timber, uaua, sometimes (I think, correctly) huahua ; the second horizontal timber, haiwai ; the heavy bottom totara log, huahua-kaiwai ; the angle stakes holding same, noko ; the angle log at head of weir, noko-panawai ; the return angle or wing at foot, hoi : the side posts holding same, pou-riri (sometimes turn) ; the sliding timber, rango ; the same timber when fastened down, huapae ; the water between the fences, ihonui ; water outside of fences, auroa. When a fresh is in evidence two baskets are placed in position on each side, one above the other, as in the case of the small pa-tuna. Of course, in this particular style of weir a great many eels must pass without being caught ; but it would be quite impossible to net a large river in this manner thoroughly, owing to the logs and debris coming down. No doubt if the fences were to converge gradually they would be more effective in fishing, but they would be more liable to be destroyed, as the drift timbers would be caught and the weight of waters would soon be irresistible. However, a very large number of fish are taken, usually in April. The only time I saw this pa-tuna being worked upwards of half a ton of fish was taken out within twenty-four hours. This was during the tuna-heke migration. A very large pa-tuna capable of holding eight or more hinaki is called pa-tuna waharoa. There is also another built on a zigzag principle, but neither of these have I seen, nor have I been able to obtain any description of them. Trans. N.Z. Inst., Vol. L. Plate XXVII. Fig. 1. — Utu, or lamprey-weir, at Parikino, Whanganui River. looking down-stream. Fig. 2. — Utu, or lamprey-weir, at Parikino, Whanganui River, looking up-stream. Face p. 312.] Trans. N.Z. Inst... Vol. L. Plate XXVIII. Figs. 1, 2.—Hindh% herehere of different patterns. Fig. 3.— Koroteie lying under whata tapu {tapu storehouse) at Tawhata. Whanganui River. Trans. X.Z. Inst., Vol. L. 4\fV > t W^ Plate XXIX. ■ | lT K- SMhXm X\3\f\ jv* $%l Hinaki pattern (ripeka). Traxs. N.Z. Inst.. Vol. L. Plate XXX. Vt * tMftfflll ' 4 ■ , ■ ill M '-*. *>fvk '"'itti Hinaki pattern, showing arrangement of ribs. Downes. — Eels and Eel-weirs. 313 The Utu. a Weir for taking Piharau [Lampreys). This is built at right angles from the shore, and is built on dry ground by the side of a rapid, being only operated during flood-time (sec Plate XXVII. figs. 1 and 2). It is like the pa-tuna, a fence built with closely driven stakes and horizontal cross-timbers, heavily matted or thatched on the up-river side, and strongly braced on both up- and down-stream sides. As the utu has to stand the full force of flood-waters, the bracing is exceptionally strong, upper and lower rows being thrown out at an .ingle from both horizontal stays on each side. Strong as they are, they seldom last more than a season. The photographs in Plate XXVTI were taken at Parikino, Whanganui River, about five years ago. but of the original not a vestige now remains. The fence is constructed so that the water is blocked at regular spacings, usually about 5 ft. wide, and can escape at alternate spaces of about 2 ft. The up-stream braces are fixed so as to lead the water towards the open parts, as is shown by the illustration. The matting is of bracken and manuka brush— principally bracken. Posts are usually fixed below the fence each side of the water-channel to hold the poha, the circular vine of which for this style of weir is generally attached to a forked piece of wood resembling an inverted Y, or to two pieces of straight wood spliced and tied together as an inverted V (see fig. 8). On the down-stream side a sort Fig. 8. — Poha frames for large pu-hnui or utu. of floor is laid of manuka or fern, pressed down with thin manuka poles, which are held in position by pegs driven across them both ways. The piharau congregate in the slack water immediately behind the wall part of the fence, but directly they attempt to go through the weir-opening they meet the full force of the swollen current and are thrown back into the nets. Names of the utu parts are as follows : The stakes are called pou ; the top horizontal pole, huahua ; the second horizontal pole, ngakau ; the braces, noko ; the blocked part of fence, pawai : the opening, ngutu : the floor, whariki ; the poles holding down the floor, tapatu : the crossed pegs holding down the poles, tarapi. Hinaki. Eel-baskets, or hinaki. as they are called, are of several shapes, sizes, and patterns. They are hard or flexible, regular in construction, and as a rule cone-shaped. They are small at each end, bulging out in the middle, 314 Transactions . and are usually from 5 ft. to 6 ft. long and 18 in. to 2 ft. 6 in. in diameter at the widest part. One end is secured tight by a lid ; the other returns inwards by a neat curve as a funnel, and finishes with an opening 3 in. or so in diameter about 1 ft. or 18 in. down the net. Hinaki were formerly chiefly constructed of aerial roots of kiekie (Freycinetia Banksii) steeped in water till pliable, and were light, strong, and flexible ; but I am informed that the akatea vine (Metros id eras albiflora) and aka tororaro gave the best results both as regards strength and lasting qualities. The pohue vine (Calystegia sepium) was also used in the construction of the hinaki, but was called aka korewa when so used. Another vine, growing on stony plains, was also used for fine work and flexible springy baskets, but my informant was unable to remember the name. The kiekie, probably the most common, being the easiest to procure, was also the poorest, as Fig. 9. — Types of hinaki : a, hinaki herehere ; b, hinaki tatairangi ; C, hinaki waharoa or hinaki aranvi. even with care it only lasted from five to seven years. Sometimes in a pattern called pakipaki thin manuka was used for the long strips which were laced on to kareao hoops with small vines, but I have never seen a basket made in that manner, although 1 understand they were common. In these modern days kareao and sometimes even wire netting are easily obtained substitutes, and it seems to me that the days of the old-time hinaki are numbered. Indeed, as European ideas and methods are gradu- ally growing into favour and practice with the Maori, the old systems of obtaining food are gradually falling into disuse. Twenty-five years ago pa-tuna were common enough in almost every river and stream on the west coast of the North Island ; now there are only two in the Whanganui, practically the home of the pa-tuna, and 1 do not think that farther south even one will he found. Trans. X.Z. Inst., Vol. L. Plate XXXI. Face p. 314.] Hinaki pattern (elongated ripeka) Trans. X.Z. Inst.. Vol. L. Plate XXX IT. Hinaki pattern (pakipaki or aurara). Trans. N.Z. Inst., Vol. L. Plate XXX I II. Maw BHBBnL -* -^ ^ .^ -f - ^ ^i ». Hinaki pattern (pliable). Trans. X.Z. Ikst., Vol. L. Plate XXXIV. s Downes. — Eels and Eel-weirs. 315 For the hinaki that was used for setting at pa-tuna the trap, or return part, was woven separately and laced on the hinaki afterwards, giving a continuation of the poha lead. Otherwise it was made in one piece. Some- times for the bait-setting traps loose ends of vine ran together at the inner end of the net funnel, through which the eels could easily push their way but which securely blocked egress. The common shape was called titika. It was used entirely for catching tuna-toke with bait. In this as in the other shapes all the enlarging or reducing was done by adding or drop- ping strands. Hinaki herehere (fig. 9, a) was another style of trap used for baiting only. The bottle shape with parallel sides bulging at one end was called pae, sometimes tatairangi (fig. 9, b, and Plate XXVIII, figs. 1 and 2), and the large-mouthed hinaki for placing in the pa-tuna, was called whakapuwaii and by some waharoa and aranui (fig. 9, c). This hinaki had usually a lid for both ends to hold eels if used as a storing- basket. Puhara and yuwai were baskets made without a trap end, used for keeping eels alive in the water. A similar basket for holding live lamprey was called korotete. Occasion- ally these baskets were protected by vine rings tied on outside. A very fine specimen photographed by the writer, lying under a whata tapu (tapu storehouse) at Tawhata, about 120 miles up the Whanganui River, is manu- factured in this manner (Plate XXVIII, fig. 3). Hinaki-pitau, a very small trap of the hinaki pattern used for catching whitebait, was very closely woven of a thin vine called kaii* Another net for catching whitebait was called hauwai. It was in shape something like a huge scoop without the handle, and is now obsolete. As a boy I saw one of these used by a woman in the Rangitikei River, but that is the only one I have ever seen. It was made of a rush which I regret to say I have lost the name of. In the Whanganui district the whitebait is called karohe when the shoals first go up-stream in the spring. Hinaki and Korotete Patterns. There are at least three patterns, with their modifications and variations, used in weaving hinaki and korotete, one of the finest being called ripeka. It is rather complicated, but very strong (see Plate XXIX). The ribs run the whole length of the hinaki in a continuous spiral, and are placed about 1 in. apart. It will be seen from the accompanying photograph that the diagonal vines from left bottom corner to right top corner pass round the ribs at each intersection, passing under the two-ply twist that holds all together at the same time. Plate XXX shows a modification of the same pattern, the twist round the rib taking place at intervals of between 2 in. and 3 in. Part of tie basket-work was cut away in the original of this illustration in order to show the arrangement of the ribs, which gradually grow stronger towards the middle of the net. Plate XXXI shows an elongated variation of the same pattern, and Plate XXXII the common oblong pattern called pakipaki and also heau- rara (? aurara). In the illustration the ribs are shown close together, and * The long, slender, and flexuous branches of the young plants of matai (Podo- carpus spicatus), which young trees are called kai and mai by natives, were used in the manufacture of eel-pots. Possibly this is the material alluded to. 316 Transact io ns. tied at irregular intervals by the long vines passing round them, but in many hinaki of a somewhat similar pattern they are arranged at intervals of about 6 in. In Plate XXXIII is shown a flexible basket of a somewhat similar pattern to above, made of the kaii* vine. The ribs are two-ply twist of the same material, but somewhat thicker, and are placed four or five close together within the spate of 3 in. or 4 in., a similar distance being spaced without ribs. A basket constructed of this material is very fine, light, springy, and pliable, and must have taken a long time to manufacture. Plate XXXIV shows the common basketware pattern made with split kareao. I have been unable to obtain a name for this basket except hinaki kareao. The Whanganui natives call this vine karewau. It is said that it usually takes an expert about a week to weave an ordinary hinaki about 5 ft. long of the heaurara pattern, which is certainly the simplest. The parts of the hinaki are as follows : The ribs are called potaka : the ribs when continuing in a spiral, whenu : the lid, taupoki : the net or funnel- shaped entrance for pa-tuna hinaki. akura (also kuao and te ure) ; twisted vine handle at top, popoia ; manuka handle at side, kaharoa : eye for securing lid, popoki ; pin for same purpose, taheke (and also kopiha) ; the two-ply twist following round the ribs, whatu : the vine hinge, toroaka : outside protecting vines, porowhita popoki. Tan n ing ( Whakawah i ) . Any one who has looked at hinaki closely will have noticed that some of the oldest types are sometimes black in colour. This is due to a tanning process that was formerly employed in order to lengthen the life of all hinaki, but which is now entirely omitted in the manufacture, and has not been used for many years. Quantities of maire and whinau (hi nan) bark were gathered, parcelled up, wrapped in leaves, and placed in an umu for prolonged steaming. A special trough, called patua, made of the inner bark taken from a large totara tree was provided. This bark was taken off in one sheet, first cut at both ends with a stone adze at the required length, and then prized off with a maire or akeake lever made especially for the purpose with a fire-hardened point. When a piece of bark was removed in this manner without split or flaw the ends were gradually softened by steam in an umu until they were quite pliable and could be bunched and tied. This bark receptacle was used because it did not absorb the tannin as did a canoe or trough cut out of wood. The softened pieces of maire bark were rubbed and worked by the hands until they crumbled away, and the whinau, which would not crumble, was broken as small as possible, and the mass was left in the patua just covered with water until the juices thoroughly impregnated the water. The bundles of vines intended for hinaki wine placed in the dye and left for one or two nights, according to the thickness and texture of the bundles so treated. The process was called irhakaira/ii. * Some natives give tliis vine as the Mi, and say it is found near the sea ; but I am unable to give its botanical name. Hogg. — On certain Tripolar Relations. 317 Art. XXXII. — On certain Tripolar Relations: Part 111. By B. G. Hogg, M.A., F.E.A.S., Christ's College, Christchurch. [Read before the Philosophical Institute of Canterbury, 1st November, 1916 ; received by Editors, 22nd December, 1917 ; issued separately, 24th June, 191S.] The equation of the circle of radius p having its centre at the point 0, whose trilinear co-ordinates are (a0, fi0, yD), is U ee aa0X + b/30Y + c7oZ - 2ES0 - 2 a p2 = o (i) Let d be the distance of O from H, the centre of the circle ABC. If U pass through H, then R2 (aa0 + b(i0 + cy0) - 2ES0 - 2 a d2 = o ; i.e., 2ES0= 2 a (E2 - d2) : hence U may be written aaQX + b/3QY + cy0Z == 2a (R2 + p2 - d*) (h) If the circle U cut the circle ABC at the angle 0, then R2 4 p2 — d* = 2Ep cos 0, whence U = A> ± P cos B> Vo ± p cos C , the negative sign being taken for internal contact. If U reduce to a point-circle, (ii) then takes the form ««0X + bp0Y 4- c7oZ = (aa0 + b(3a + c7o) (R2 - d?) ; i.e., aaG (X 4- & - R2) + bf30 (Y + d" -■ R4) 4- Cy0 (Z + & - R2) = o. Let X = p,2, Y = p22, Z = p32, and let the radii HA, HB, HC subtend at O the angles A., p., v respectively ; we then have aacp! cos A. + b/3,p2 cos p 4- cynp:. cos v = o (iv) 318 Transactions. The following particular cases of (iv) are of interest. For the ortho- centre, in-centre, centroid, and symmedian point respectively sin A cos A + siu B cos p + sin C cos v = o A ^ B C COS -- COS A + COS — COS p + COS .— COS v — 0 A A A mr COS A + IU.2 COS p + ^h COS V = o am,! cos A + bin., cos p + cm?, cos v — o, where m1( mz, and m3 are the medians of the triangle ABC. If 0 be either of the two points whose pedal triangles are equiangular, then, since for these points ap1 = bp.2 = cpA, aQ COS A + (S0 COS p + y0 COS v = 0. If 0 be the focus of a conic inscribed in the triangle ABC, then the equation of the conic is a \/X0a0a + b VTof3of3 + c v Zo7o7 = o. Comparing this with the equation of the maximum inscribed ellipse, v aa + Vb(3 4 v ' cy = o, we have aX0a0 = bY0/30 ■-= cZ0y0, whence cos A cos p, cos v AO~ + ~B0~ + "CO" = °' For the Brocard ellipse this gives COS A COS fi. cos v BC . AO ' CA . BO ' AB . CO Let U1 be the result of substituting in U the co-ordinates (X1, Y1, Z1) for (X, Y, Z). Suppose a circle of radius p1 concentric with U to pass through the point (X^Z1), then U1 = aaQXl + 6&Y1 + cy.Z1 - 2ES0 - 2a P2 0 = aaQXl + 6/3QY' + cy^1 - 2BS0 - 2 a p1 2 .-. U1 = 2 a (p1 a - p~) = 2 a t1 2, where t1 is the length of the tangent from (X^Z1) to the circle U = O. Let tlt t.,, and ts be the lengths of the tangents to the circle U from A, B, C respectively : then 2 a t? = b/30c2 + cyjb1 - 2 a (B2 - cV- + p2) ; 2 a (tf + B2 - d.2 + p2) = 6y80c2 + cy0b\ We have X0 = t£ + p'2, whence, if OH subtend at A, B, and C the angles 0, , + cp. cos C cos f =2a. From the equations aPl cos 6 /50 y0 bp2 cos 0 _ y0 aQ cP3 cos i/r _ a /30 r — -j- i > 1 > 7 — 1 — r> be b c ca o a ab a b we see that if O lie on the trilinear polar of the symmedian point BC2 AO cos $ + CA2 BO cos 0 + AB2 CO cos ^ = o. Solving for a0, /30, y0 from the above equations, and substituting in he equation of the circle ABC, we obtain the relation BC v'OA cos 0 + CA \/OB cos <£ + AB \/OC cos~^ = o for any point O on the circle. If tQ be the length of the tangent to any circle from the middle point of BC. then 2 A ti = aa0c2 + c7oa2 - 2 (RS0 + A P2) 2 a t2 = aa0b2 + bft0d2 - 2 (RS0 + a p2) 2 a t2 = aa0m> + f (&& + cy0) - 2 (RS0 + a p2) where w, is the median drawn through A. Hence 2 A (ti + t2 - 2tQ2) = aa0 (b2 + c2 - 2m?) + ~ {bft0 + cyj Zi a2 _ »•«•. 41 + «»! = 2t0a+^-', A an extension of the Theorem of Apollonius. If U be the polar circle of the triangle ABC, then U = tan AX + tan BY + tan CZ - 2 a = o .-. 2 a t2 = k (c2 tan A + a2 tan C - 2 a), where K = 4R2 cos A cos B cos C, which reduces to t22 = ca cos B. Also t2 = ab cos C, hence £22 + tJ = tr. If in the triangle ABC the angle A be obtuse, then the sum of the squares of the tangents to the polar circle from B and C is BC2. If U = o pass through the point (XjYjZi), then the locus of O («oA>Yo) is the circle V = aaX1 + b/SY, + cyZj - 2RS - 2 a p2 = o. '320 Transactions. If tlt U, t8 be the lengths of the tangents to the circle V from A, B, C respectively, then Xx = tx2 + p2, Y1 = U2 -f p'2, Z = tr 4- p'2, and the equation of the circle takes the form V= (t2aa + t.?b(3 + ts2cy) (aa + bfi + cy) - abc S = o. If V touch the circle ABC, then expressing that the radical axis of the two circles is a tangent to S we have at, + bt2 + ct, = o, from which we obtain Ptolemy's theorem if we suppose V to reduce to a point-circle. This extension of Ptolemy's theorem may be proved geometrically as follows : — Suppose the circle V to touch the circle ABC' at the point O on the arc BC, and let AO, BO, CO meet V in the points D, E, F respec- OP OR tively ; then Uj == BO . BE and t2 == CO . CF. Also ~ = ^, and O r O C "D"tl AT) therefore — = — , hence t2 : t2 = OB'2 : OC2 ; CF OC i.e., tx : t., : ts = OA : OB : OC. By Ptolemy's theorem BC . OA = AC . OB + AB . OC ; i.e., at-i = bt^ + ctA. If t be the length of the tangent to the circle V = o from any point P ("cft,yo). then 2 a t2 = aa0t2 + b/3Qt2 + cy0t? - 2RS,,. For the circle BPC, t = t, = ts = o. Consider now the circles BPC, CPA, APB. We have aaJS = b{3JS = cyjy = 2ES0. Hence """ + 6& + c7o __ 1 , 1 . 1 HenCe ^RS^ t* + tf + t2 111 1 l-e> n + ri + 7i t2 t£ ' t,2 R'2 - a1'2 where a7 is the distance of P from the circum-centre of the triangle ABC. If P be the symmedian point of the triangle ABC. then atx = bt2 = cts : if G be the centroid of the triangle L2 = t? — t2 — ^ 2 (a2). If the circle V reduce to a point Pj whose tripolar co-ordinates are (XjYjZi) we have X,«a + Y,bf3 + Z,cy = 2RS. For a point-circle at P.2 (X2Y.2Z2) X./ia + Ya6/8 + Z,cy = 2KS. Hence the radical axis of the pair of circles is (X, - X,) aa + (T, - Y,) b/3 + (Zj - Z,) cy = o. Hogg. — On certain Tripolar Relations. 321 X Y 7 If P1} P2 be inverse points determined by the equations - — -: = — , (■ 11 1 n 1 1 X.i — X2 Yj — Y0 Zj — Z.2 . , , then — = = r = - = kj — k.,, where kx and k2 are the Z wi // roots of the equation *2 [2 (aH2) — 2 2 (6c cos Aww] - 2k a&c [2 (a cos A/)] + a26V2 = o. Hence the equation of the line bisecting perpendicularly the above pair of inverse points is laa + mbfi + ncy = o. The two points whose pedal triangles are equilateral are determined by the equations a2X = Z>2Y = c2Z. Hence these points are equidistant from the line — I- r + — = o, which is therefore perpendicular to the Brocard a b c diameter 2 [a2 (b2 — c2) X] = o, on which the points lie. The two points whose distances from A, B, C are proportional respec- X Y 7 tively to a, b, c are given by the equations — ==- = —: they therefore (At (J C lie on Euler's line, 2[(&2 — c2) X] = o, and are equidistant from the line a?a + bsfi + c3y = o. Let two pairs of inverse points be determined by the equations — =-- = - and — = -- = — ; the centre of the circle through them will be determined by the equations lxaa + mib/3 + nxcy = o Uaa + mjbfi + n.2cy = o, whence fla : 6/3 : cy = m^ — ra.yH, : w^ — n2l\ : Z^ — Z2mx, and the equation of, the circle will be (to!»2 — m2n1) X + (^1^2 — n-A) Y" + (^m2 - Z2??i]) Z — o. The two pairs of points will lie respectively on the diameters (m, — iij) X -f (wj — Zj) Y + (Zx — m:) Z = o (ra2 - ?i2) X -f (n.2 — L) Y + (Z2 — ra2) Z = o. We now proceed to find the equation in tripolar co-ordinates of the inverse of the circle U = o with respect to S, the circum-circle of the triangle ABC. U = ZX + mY + nZ - h2 = o S = a cos AX + b cos BY + c cos CZ — abc = o. Let P be any point on U and Q its inverse. Let (X, Y, Z), (X1, Y1, Z1) be the tripolar co-ordinates of P and Q respectively, then X Y^ Z HP2 XI = Y1 == Z1 = ~W' where H is the circum-centre. Hence HP2 (ZX1 + mY1 + nZ1) = /i2E2. 11— Trans. 322 Transactions. The equation of the circle of radius HP concentric with the circum- circle is a cos AX + b cos BY + c cos CZ - 2 A E = 4EHP2 sin A sin B sin C. H ftficft HP2 (a cos AX1 + b cos BY1 + c cos CZ1 - 2 a E) = 2 aB\ Eliminating HP2, the equation of the inverse of U becomes a cos AX + b cos BY + c cos CZ - 2 a E _ 2 A E IX + mY + ?iZ ~P~ or h* (S + 2 a E) = 2 a E (ft2 + U) ; i.e., /rS - 2 a EU = o. The equation of the circle which is the inverse of the line ZX + mY + nZi — h? = o takes the same form as the above, subject to the condition I + m -+■ n = o. The equation of the circle which is the inverse with respect to, the circle ABC of the line pa + qfi + ry = o is aX {p cos 2A + q cos (A — B) + r cos (C — A)} + bY {p cos (A -- B) + q cos 2B + r cos (B - C)} + cZi {p cos (C - A) + q cos (B - C) + r cos 2C} = abc (p cos A -\- q cos B + r cos C). The equation of the circle which is the inverse with respect to the circle ABC of the line — (- ^- -f 5- = o is a o c a cos (A — w) X + b cos (B — a>) Y +• c cos (C - w) Z — abc cos oo, where w is the Brocard angle of the triangle ABC. PROCEEDINGS. 11s PEOCBEDINGS OP THE NEW ZEALAND INSTITUTE, 1917. FIFTEENTH ANNUAL MEETING. Wellington, 29th and 30th January, 1918. The annual meeting of the New Zealand Institute Board of Governors was held in the Dominion Museum Library on Tuesday, the 29th January, 1918, at 10 a.m. Present : Professor Benham, President (in the chair) ; Professors Kirk. Marshall, Segar, and A. P. W. Thomas ; Drs. Cockayne, Hilgendorf, and Allan Thomson ; Messrs. Aston, Birks, Eliott, Ewen, Hill, Hogben, Parr, and G. M. Thomson. The Secretary called the roll, and the President apologized for the absence of Professor Chilton, who was laid aside by illness. Presidential Address.- — -The President then delivered his presidential address (see p. 338). A hearty vote of thanks to the President for his address was moved by Mr. Hill, seconded by Professor Marshall, and carried. A Committee con- sisting of the President and Dr. Hilgendorf was, on the motion of Pro- fessor Kirk, seconded by Professor Thomas, appointed to consider and report on points in the President's address which call for action, to report to this meeting. The Incorporated Societies' Annual Reports and Balance-sheets for their last financial years were laid on the table. Received. The Report of the Standing Committee was considered clause by clause and adopted (Appendices A, B, C to be discussed later). Report or the Standing Committee fob the Year ending 31st December, 1917. Five meetings of the Committee have been held during the year, the attendance being as follows: Dr. Cockayne, 2; Professor Easterfield, 5; Professor Kirk, 5; Dr. Thomson, 5 ; and Mr. Aston, 5. Hector Memorial Fund Award. — No details of the presentation to Sir E. Rutherford have yet been received, although medal and prize were sent to England over a year ago through the Department of Internal Affairs and the Public Trustee respectively. The 1917 medal was publicly presented to Dr. C. Chilton at a meeting of the Philosophical Institute of Canterbury held on the 1st August, 1917. The Public Trustee has been nstructed to forward a cheque for the amount of the prize to Di. Chilton. 326 Proceedings. Hution Memorial Medal for 1917. — The medal was publicly presented to Dr. P. Marshall by His Excellency the Governor- General when on a visit to Wanganui in September, but no details have yet been received. Jubilee of the Institute. — This year the New Zealand Institute completes its fiftieth year of activity. The Standing Committee recommends that, owing to the war, any recognition of the Jubilee be postponed until a more convenient season. War Roll of Honour. — -The Hon. Secretary has collected data from the incorporated societies for the preparation of a Roll of Honour to be published at some future date. Volume 48, Transactions and Proceedings, N.Z. Institute. — This was issued in bulk to the incorporated societies in October, 1916, but Parliament having adjourned, a copy was not laid on the table of the House of Representatives until the 3rd July, 1917, and on that of the Legislative Council on the 5th July, 1917. Distribution of Transactions. — The Standing Committee regrets that it was not found possible to distribute the Transactions volume 49 to each member by post from Wellington. Distribution of Excess of Back Numbers of Transactions. — -A few applications from libraries have been received for partial sets, and the following should be added to the list of those who have received them : — Department of Agriculture Library, Wellington. Technical College, Wanganui. Fiji Museum, Suva. Kuaotunu Public Library, Kuaotunu. Mailing-list. — The following has been added to the mailing-list, and will in future receive the Transactions as published : — American Journal of Science (Editors), Yale University, New Haven, Con- necticut, U.S.A." Resolutions of the Standing Committee — Banking Account : It was resolved that only the following be authorized to operate on the histitute's banking accounts : viz., the Hon. Treasurer, the Hon. Secretary, and Professor Easterfield. This to coirtinue in force until revoked in writing. Major Brourts Bulletin. — -It was resolved that 400 copies of Major Broirn's bulletin be printed. National Efficiency and Research. — A most important feature in the history of the New Zealand Institute was the appeal from the Government National Efficiency Board for advice on the relation of scientific and industrial research to national efficiency. On the 7th June, 1917, a letter from the Chairman of the National Efficiency Board (Mr. William Ferguson) was received by the Standing Committee, asking its advice, and suggesting that the Committee should hold a special meeting to consider the following resolution forwarded by the National Efficiency Board : — " Scientific and Industrial Research : Resolved, That the Standing Committee of the New Zealand Institute be asked to advise the Chairman on the matter, with power to consult other scientific men technologists in the Dominion, and the Committee be requested to hold its first meeting on a date when, if possible, the Senate of the University will be in Wellington, so that those members of that body who are members of the Committee can attend its deliberations/' The Standing Committee referred the matter to the President of the Institute (Professor Benham, Dunedin), asking for authority to resolve itself into a committee with power to co-opt members outside those already on the Board of Governors, to receive suggestions from the incorporated societies and other bodies and persons interested in any scheme of organization of research and industry, to collect these suggestions received, and to prepare a scheme for submission to the full Board of Governors. A confidential repoit on the organization of scientific and industrial research, by Dr. J. Allan Thomson, dated the 20th July, 1916, to the Hon. the Minister of Internal Affairs, was used as a basis of discussion, with the consent of the Hon. the Minister, who sup- plied a limited number of typed copies for private circulation. At a further meeting on the 5th July the Standing Committee received a letter from the President empowering the Committee to proceed in the direction desired. The Committee therefore co-opted the following: Dr. C. E. Adams, Mr. D. C. Bates, Dr. C. A. Cotton, Mr. William Ferguson, Dr. Frengley, Mr. F. W. Furkcrt. Mr. W. H. Holmes, Mr. H. H. Jackson, Mr. J. C. Lewis. Dr. J. S. Maclaurin, Mr. W. B. Montgomery, Mr. P. G. Morgan, Mr. W. H. Morton, Mr. Evan Parry, Dr. C. J. Reakes, and Mr. E. Phillips Turner. Certain bodies were also asked to select someone to represent them on the Com- mittee', and the following were so elected : The Industrial Corporation of New Zealand appointed its president, Mr. F. J. Evans ; the Workers' Education Association of Fifteenth Annual Meeting. 327 Wellington appointed Professor T. Hunter ; and the Council of Education appointed Mr. George Hogben to represent it on the Committee. The name of this Committee adopted was the New Zealand Institute's Scientific and Industrial Research Committee. Mr. George Hogben, C.M.G., was unanimously appointed permanent Chairman, and seven meetings were held in September, October, November, and December, the attendance being as follows: Mr. George Hogben, 7 ; Dr.. Adams, 6; Mr. Aston, t> ; Mr. Bates, 4; Dr. Cockayne, 0 ; Dr. Cotton, 6; Pro- fessor Easterfield, 4 ; Mr. Evans, 7 ; Dr. Frengley, 5 ; Mr. Furkert, 4 ; Mr. Ferguson, 4 ; Professor Hunter, 6 ; Mr. Holmes, 6 ; Mr. Lewis. 6 ; Dr. Maclaurin, 6 ; Mr. Mont- gomery, 4 ; Mr. Morgan. 7 ; Mr. Morton, 1 ; Mr. Parry, 2 ; Dr. Reakes, 4 ; Dr. Thomson, (i ; Mr. Turner, 5 ; Mr-. H. Hill, 1. The Honorary Secretary of the New Zealand Institute was elected Honorary Secre- tary of this Committee. A sub- committee, consisting of Mr. George Hogben and Dr. Thomson, was set up to prepare a synopsis of the various schemes at present adopted by other countries for advancing science and industry. This was drawn up as a report by the sub-committee, submitted to the Hon. the Minister of Internal Affairs on the 2nd October, 1917, and at once published as a parliamentary paper, H.-47, 1917, Organiza- tion of Scientific and Industrial Research, and laid before Parliament, then sitting. The Committee resolved that it was necessary that a research scheme should be prepared. A sub-committee was set up to draw up a list of suitable bodies and persons to circularize throughout the Dominion asking for any suggestions which they had to offer. The replies which were received were summarized by the Chairman. The Committee took the scheme of the Wellington Philosophical Society (see Par- liamentary Paper H.-47, 1917) as a basis for formulating a new scheme, and duly considering (a) the replies which had been received in answer to the Committee's circular, (b) the opinion of certain prominent scientific research workers who happened to be in Wellington at the Board of Studies meeting of the New Zealand University. Certain recommendations were drawn up advising the setting-up of a Board of Science and Industry, and prescribing the method of election or of appointment, and also the functions of the members of this proposed Board. The President of the New Zealand Institute having given his permission for this Committee to send their report in to the Government without consulting the Board of Governors as a whole (who nevertheless were kept informed by circular of the progress of the scheme), the report was sent in to the Chairman of the National Efficiency Board on the 9th November, 1917. At the request of the Hon. the Minister of Internal Affairs, the Committee waited upon him on the 12th December, 1917, to hear his views and to give any advice desired as to the advancement of science and industry. The Minister promised to support the scheme drawn up by the Committee. Mr. Ferguson informed the Hon. the Minister that the recommendations of the Com- mittee would receive consideration at the meeting of the National Efficiency Board to be held on the 8th January, 1918, and were then to be sent on to the Government. (Your Committee is informed that this has now been done.) At an early stage of the Committee's deliberations a motion was carried urging the Government to place on the supplementary estimates £2,000 for the purpose of promot- ing scientific research. This motion was forwarded through the National Efficiency Board to the Government. The Prime Minister has informed the Board that the following sums have been placed on the estimates under the Department of Internal Affairs : — £ (1.) Dominion Laboratory — Scientific research .. .. 500 (2.) Miscellaneous Services — Grant to the New Zealand Insti- tute for research work . . . . . . . . 500 (:{.) Dominion Museum — Scientific and industrial research .. 250 £1.250 As requested, the Standing Committee has extended the powers of the Scientific and Industrial Research Committee so that it may undertake the preliminary work of collecting data concerning New Zealand's industries and research workers, and facilities for carrying out the work. The Hon. the Minister of Internal Affairs having informed the Committee that he was prepared to take steps at an early date to inaugurate a Dominion scheme of scientific and industrial research by making a preliminary census of past research, actual problems of industry awaiting solution, and of available labora- tories and research workers, and that there was a vote of £250 on the Museum estimates available for the purpose, the Committee advises that the Director of the Dominion Museum should undertake such census, and that a Committee of the New Zealand Institute shoidd co-operate with him. 328 Proceedings . Annual Reports and Balance-sheets of the following incorporated societies have teen received and are now laid on the table. No reports have been received from the Wanganui or the Nelson Societies. Auckland Institute, to 22nd February, 1917. Philosophical Institute of Canterbury, to 31st October, 1917. Otago Institute, to 30th November, 1917. Hawke's Bay Philosophical Institute, to 1st December, 1917. Manawatu Philosophical Society, to 30th November. 1917. Wellington Philosophical Society, to 30th September, 1917. Auckland Institute Jubilee. — An illustrated pamphlet entitled The First Fifty Years of the Auckland Institute and Museum, and its Future Aims, a Jubilee Sketch, was pub- lished by the Auckland Institute in September, 1917. A copy is now laid on the table. Public Meeting of the New Zealand Institute. — The desirability of holding a public meeting of the New Zealand Institute to arouse some public interest in scientific affairs, more especially in relation to industry, was discussed by the Committee, and Dr. Hector, Dr. Allan Thomson, Mr. Ewen, and the Hon. Secretary were appointed a sub-committee to' make arrangements to hold it on the 30th January, 1917, the night of the last annual meeting, and the Town Hall was engaged for the purpose. It was not found possible, however, to obtain the necessary support at the time, and the matter was allowed to drop. Honorary Treasurer s Reports.— The financial statements of the Hono- rary Treasurer, Mr. C. A. Ewen, comprising (a) Receipts and expenditure, (b) assets and liabilities, (c) the Carter Bequest, the Hutton Memorial Fund, and the Hector Memorial Fund, all of which were duly audited and certi- fied by the Auditor-General, were adopted on the motion of Mr. Ewen, seconded by Mr. Birks. The Public Trustee's reports on his administration of the Carter Bequest, the Hutton and the Hector Funds for the year ending 31st December, 1917, were adopted on the motion of Mr. Hill, seconded by Mr. Ewen. Statement of Receipts and Expenditure for the Year ending 31st December, 1917. Receipts. Balance at 31st December, 1916 .. Post Office Savings-bank in- terest to 31st December, 1917 .. Government grant (30th June) Publications sold City Corporation, refund rent hall not used Wanganui Philosophical So- ciety levy for year ending 31st December, 1916 Hawke's Bay Philosophical Society levy for year 1916 Nelson Institute levy for 1916 Grant for research refunded by Mr. D. Petrie Grant from Treasury (1st February) Grant from Treasury (28th March) £ s. d. Expenditure. Hire Concert Chamber, Town £ s. d. 561 11 10 Hall, for 30th January . . McKay, custodian, preparing 2 2 0 room and packing 3 0 0 15* 6 1 Miss Bates, typing 4 10 0 500 0 0 Government Printer, Vol. 48, 47 19 5 authors' copies and printing 599 17 0 Governors' travelling-expenses 35 10 6 2 2 0 Grant for research to Philo- sophical Institute of Canter- bury 110 0 0 6 17 6 Grant for research to Welling- ton Philosophical Society 75 0 0 6 0 6 Grant for research to Hawke's 3 10 0 Bay Philosophical Institute Grant for research to D. 20 0 0 20 0 0 Petrie Fire-insurance premium, £1,500 20 0 0 120 0 0 on library 5 0 0 Hon. Editor, petty expenses 4 0 0 20 0 0 Hon. Secretary, petty ex- penses 5 0 0 Bank charge 0 10 0 Balance in — P.O. Savings- £ s. d. bank .. 333 14 7 Bank of N.Z. 85 3 3 418 17 10 £1,303 7 4 £1 .303 7 4 Fifteenth Annual Meeting. 329 Statement of Liabilities and Assets at 31st December, 1917. By Balance in Bank of New Zealand Balance in Post Office Savings-bank Hector Memorial Fund and per contra Hutton Memorial Fund and per contra Carter Bequest and per contra Institute levies for year 1917 (per list) Authors' copies and books sold To Special grants for research purposes Government Printer's account, authors' copies, &c Cost 1917 volume. No. 49 New Zealand Express Company By Balance To Balance Liabilities. A ssets. £ s. d. £ s. 85 3 333 14 d. 3 7 .. 1,106 13 9 1 ,106 13 9 787 11 5 787 11 5 .. 4,138 5 11 4 , 138 5 124 7 7 6 II 6 1 45 0 0 88 13 0 577 0 0 m t 3 13 6 163 15 1 £6,746 17 7 £6 ,746 17 7 £163 15 1 Against this debit balance the Institute has a large stock of Transactions for sale, and possesses a very valuable library. Hector Memorial Fund. — Statement of Receipts and Expenditure for the Year ending 31st December, 1917. Dr. Cr. £ s. d. £ s. d. By Balance brought forward .. .. .. .. 1,093 18 0 Public Trust Office— £ s. d. Interest, 31st December, 1916, to 31st December, 1917 . . 48 1 4 Bonus for year ending 31st December, 1917 .. .. .. 4 15 11 To New Zealand Institute — Hector Prize, awarded Professor Sir E. Rutherford. Postages Balance in hands of Public Trustee By Balance 40 0 0 0 1 6 1,106 13 9 52 17 3 £1,146 15 3 £1,146 15 3 £1,106 13 9 Hutton Memorial Fund. — Statement of Receipts and Expenditure for the Year ending 31st December, 1917. Dr. By Balance brought forward Public Trust Office— £ s. d. Interest, 31st December, 1916, to 31st December, 1917 . . . . 33 14 S Bonus for year ending 31st March. 1917 .. .. .. 3 6 4 To Balance in hands of Public Trustee £ s. d. 787 11 5 £787 11 5 Cr. £ s. d. 750 10 5 1 0 £787 11 5 By Balance £787 11 5 Dr. Cr £ s. d. £ s. d. 3,944 3 5 177 5 10 17 1 11 0 5 3 4,138 5 11 £4,138 11 2 £4,138 11 2 .'l.')H Proceedings. Carter Bequest.— Statement of Receipts and Expenditure for the Year ending 31st December, 1917. Bv Balance brought forward Public Trust Office- Interest from 31st December, 1916, to 31st December, 1917 Bonus interest from 31st December, 1916, to 31st December, 1917 To Public Trustee- Commission Balance in hands of Public Trustee By Balance .. .. .. .. .. .. £4,138 5 11 Financial Position. — After a general discussion on the financial position of the Institute it was resolved, on the motion of Mr. Ewen, seconded by Dr. Cockayne, That for every copy of Volume 50 of the Transactions re- ceived by the incorporated societies a contribution of 2s. 6d. towards the cost of printing shall be made during the current year by such society. On the motion of Professor Thomas, seconded by Mr. Hill, it was resolved, That strong representations be made to the Government by the New Zealand Institute with the view of obtaining an increased grant of £750 for this year for the publication of the Transactions and other scientific work. Hutton Grant for Research. — Mr. G-. M. Thomson, Chairman of the Porto- bello Fish-hatchery, read a further report of the work carried out during 1917, which had been assisted by a grant from the Hutton Fund in Januarv, 1916. Hector Award for 1918. — -The recommendations of the Committee of Award — Professor Chilton, Dr. Cockayne (convener), Professor Easter- field, and Professor P. Marshall — was received in a sealed envelope by the President, and the recommendation awarding the medal and prize to Mr. T. F. Cheeseman, of Auckland, was adopted on the motion of Professor Thomas, seconded by Mr. G. M. Thomson. Report of the Hector Memorial Award Committee. The members of the Hector Memorial Award Committee for 1918 — Professor C. Chilton, Dr. L. Cockayne, Professor T. H. Easterfield, and Dr. P. Marshall — having carefully considered the claims of all botanists who, in their opinion, might be entitled to receive the Hector Memorial Medal and Prize, have unanimously decided to recom- mend Mr. T. F. Cheeseman, F.L.S., F.Z.S., as the recipient of the award. This they do on the grounds not only of the great excellence of Mr. Cheeseman' s published researches on New Zealand systematic botany, phytogeography, and floral biology, winch have been carried on without a break since the early " seventies" of the last century, but also because of the supreme influence of his work, especially of his admirable Manual of the New Zealand Flora, upon botanical investigation throughout the Dominion. Leonard Cockayne, Convener of the Committee. Publication Committee's Report. — On the motion of Dr. Cockayne, the Publication Committee's report was adopted. On the motion of Dr. Hil- gendorf, seconded by Professor Segar, it was resolved, That the question of inserting the date of receipt of papers by the Honorary Editors be left to the Publication Committee. Fifteenth Annual Meeting. 331 Report of the Publication Committee. Sixty papers were offered for publication, and of these fifty were accepted by the Committee for publication in Volume 49 of the Transactions. It' was decided to deposit the manuscript of another paper in the library of the New Zealand Institute and to publish the title, so that this might be indexed and give information to other workers as to the availability of the work. It is proposed to treat similarly other papers so deposited in the future. The remainder of the papers were withdrawn, held over, or declined. Volume 49 of the Transactions and Proceedings of the Neiv Zealand Institute was issued on the 20th December, 1917. It contained xvi + 618 pages (of which 88 are devoted to the Proceedings), 37 plates, and many text-figures. The late publication of the volume must be accepted as a direct consequence of the war, which has depleted the staff of the Government Printing Office and supplied it with a large amount of extra work of an urgent nature. It must be remembered that the publication of scientific matter is undertaken by the Government Printing Office only in the slack season. When the pressure of urgent work for Government Depart- ments increases, the time available for work on the Institute's publications is reduced. The Committee is of the opinion that the Institute is deeply indebted to the Government Printing Office for maintaining the high standard of typographical work in the Transactions in these trying times, and, while regretting the lateness of the publication of Volume 49, realizes that the lateness resulted from uncontrollable circumstances. An innovation that has given much satisfaction is the issuing of authors' copies of articles in Volume 49 in advance of publication of the volume. This was authorized by a resolution of the Board of Governors, and has resulted in giving early publication to those papers in particular which appear in the early pages of the Transactions. Each paper bears the date of issue, and, in accordance with the resolution of the Board of Governors, the date of receipt of the manuscript by the Editors. The latter, however, is at present meaningless, since the manuscripts are generally retained by the Secretaries of the incorporated societies until the last week of December. Moreover, the only apparent reason for recording the date of receipt is to insure page priority in the volume, and no resolution to this effect has been passed. If this is the intention of the Board of Governors, it necessitates a revision of the method of transmission of manuscripts from the authors to the Editors, and also involves a departure from the present method of arrangement of papers in the volume according to subjects and authors. If this is not the intention, the insertion of the date of receipt of the manuscript seems useless. The Committee recommends that the Secretaries of the incorporated societies be requested to send the manuscripts of papers to the Editors as soon as possible after they have been read. If this is done, much earlier publication of the authors' copies than has been usual may be expected. Early receipt of the manuscripts will also allow these to be returned to the authors when extensive alterations are required, and, in some cases, will obviate the necessity of holding over such papers for a year. Bulletin No. 1, Part V, on the New Zealand Coleoptera, by Major T. Broun, was published on the 26th June, 1917, and contains 128 pages of text. Publication of the other three bulletins mentioned in the 1917 report is still delayed owing to shortage of funds. The Committee wishes to draw attention to the fact that the majority of manu- scripts as received are not well prepared for publication either as regards text or illustrations. The " Memorandum for Authors of Papers " published annually in the Transactions is evidently seldom consulted. For the Committee. L. Cockayne, ) „ v ,., ,, . ~ ' Hon. Editors. 0. A. Cotton, j The Hon. the Minister of Internal Affairs, Mr. G. W. Kussell, was at this stage welcomed by the President. The President thanked the Hon. the Minister of Internal Affairs for addressing the meeting, and for his promise of further assistance to the Institute. Report of the Library Committee. — The Hon. Librarian's report was adopted on the motion of Dr. Thomson, seconded by Mr. Hill. Report of Library Committee. The incoming exchanges have been received, registered, and placed upon the shelves. As the Institute has not been able to devote any funds to bookbinding 332 Proceedings. since 1904, the task of keeping the library in an efficient state yearly becomes more difficult. In the opinion of the Committee the time has come when the Institute should make a strong "appeal to the Government for additional funds specifically allotted to the binding of the Institute's library, which has already been offered, under conditions not yet fixed, to the Board of Science and Art. The compilation of the index cards for 1915 for the International Catalogue of Scientific Literature was referred to the Library Committee, and the cards for many of the subjects have been prepared, but have been withheld until the Board of Governors reconsidered the whole subject. The only New Zealand journals recognized by the International Catalogue are the Transactions, Proceedings, and Bulletins of the New Zealand Institute, the Journal of Agriculture, the Polynesian Journal, and the Journal of the British Medical Associa- tion (N.Z. Branch). The following important serials are omitted from the list : the Bulletins and Palaeontological Bulletins of the New Zealand Geological Survey, the Bulletins of the Dominion Museum, and the Appendices to the Journals of the House of Representatives, which last contain the annual reports of Departments and occasional scientific papers of importance. It is the duty of the New Zealand Institute, acting as the Regional Bureau for New Zealand, to make representations to the International Council as to what New Zealand journals should be indexed, and your Committee felt that it was inadvisable to send forward the cards already prepared for 1915 until the Board of Governors had considered the whole matter. We are further of opinion that the International Council should be asked to forward their annual report each year, so that affairs of the Inter- national Catalogue may come up automatically before the Board of Governors. J. Allan Thomson, Hon. Librarian. Binding of Books. — On the motion of Mr. Hill, seconded by Mr. G-. M. Thomson, it was resolved, That application be made to the Minister of Internal Affairs for a grant, as soon as circumstances permit, sufficient to provide for binding the large number of unbound publications now in the library of the Institute. International Catalogue of Scientific Literature.— On the motion of Dr. Thomson, seconded by Mr. Parr, it was resolved, That the following be added to the list of serials to be indexed for the International Catalogue cf Scientific Literature, and sent to the International Council : — (1.) Bulletins and Palaeontological Bulletins of the New Zealand Geological Survey. (2.) Bulletins of the Dominion Museum. (3.) Bulletins of the Board of Science and Art. (4.) The New Zealand Journal of Science and Technology. (5.) Appendices to the Journals of the House of Representatives. (6.) Public Health Reports. It was resolved, on the motion of Dr. Thomson, seconded by Professor Segar, That the International Council be informed that the New Zealand Institute considered it important that Government publications should be indexed in the International Catalogue of Scientific Literature, and that the Library Committee be instructed to draft a letter explaining the position. On the motion of Dr. Thomson, seconded by Professor Thomas, it was resolved, That Professor Dendy be appointed to represent the New Zealand Institute on the International Council of the International Catalogue of Scientific Literature. Bulletins. — The matter of publishing future bulletins was left in the hands of the Publication Committee to deal with at their discretion. Library Catalogue. — -Dr. Thomson explained the system of multiple card-indexing museum exhibits, and suggested that it might be made to apply to a library catalogue. Fifteenth Annual Meeting. 333 The Report of the Research Grant Committee was read, and, on the motion of Mr. Aston, seconded by Dr. Thomson, was adopted. On the motion of Dr. Hilgendorf, seconded by Professor Segar, it was resolved, That the grants already voted but not expended be renewed to the original appli- cants for the coming year. On the motion of Dr. Hilgendorf, seconded by Mr. Hogben, it was resolved, That all applications for research grants be made through incorporated societies. Report of the Research Grant Committee. (Professor Easterfield, Dr. Allan Thomson, and Mr. B. C. Aston.) The grantees for 1916-17 (see Trans, and Proc, N.Z. Inst, vol. 49, p. 580) have reported as follows : — Mr. L. Symes (Canterbury Philosophical Institute) reports (15/12/17) that no portion of the grant has been expended, owing to the difficulty of obtaining the necessary assistance. Some preliminary work has been done, but little progress can be reported. The grantee asks that the grant be renewed for the coming year. A committee of the Canterbury Philosophical Institute, consisting of Messrs. Hilgendorf, Page, Wild, Martin, and the grantee, has been appointed to carry on the work during the coming season. Mr. L. Birks (Canterbury Philosophical Institute) reports (28/1/18) that the grant has not been touched, but asks that the same sum be voted for this year. Messrs. Speight and Wild (Canterbury Philosophical Institute) report (1/12/17) having visited various localities in the South Island and having expended out of the grant of £50 the sum of £21 10s. 9d. in travelling-expenses. The work done they regard as preliminary to the attack on the problem from the commercial standpoint. Mr. H. Hill (Hawke's Bay Philosophical Institute) furnishes (20/11/17) a narrative of his journey across the Taupo Plains, with complete statements of expenditure, showing that the grant has been fully expended. Professor Kirk (23/12/17) supplies an interim report, with a statement of £12 2s. expended out of £25 voted, and asks that the unexpended balance be allowed to stand over for another year. Messrs. La Trobe and Adams report (24/1/18) that £64 Is. 6d. has been spent in the construction of apparatus, and make application for a further grant of £75. Professor Jack (Otago Institute) has not been able to do anything towards the research for which £25 was voted but not paid, and asks (15/1/18) that the grant be renewed for 1918. Mr. D. Petrie (Auckland Institute), being unable to take up the research for which £20 was granted, has surrendered his grant, and the money has been paid to the Institute. Hamilton Memorial. — The report of the Hamilton Memorial Committee of the Wellington Philosophical Society, showing photographs of the stone selected and specifications and inscriptions in Maori and English, was read and received. On the motion of Mr. Birks, it was resolved to thank the Hamilton Memorial Committee for their action. On the motion of Mr. Hogben, seconded by Mr. Birks, it was resolved, That the Standing Committee be authorized to co-operate with the Wel- lington Philosophical Society in arranging the terms on which the balance of the Hamilton Memorial Fund should be handed over in trust to the New Zealand Institute. Report of the Hamilton Memorial Committee of the Wellington Philosophical Society. The Committee has to report that in response to a circular asking for subscriptions for a memorial to the late Mr. Augustus Hamilton, the sum of £122 2s. lOd. was received. After consultation with the family of the late Mr. Hamilton, the Committee decided to have a suitable monolith erected over the grave at Russell, Bay of Islands. A number of designs were considered, and the one prepared by the Government Architect, Mr. J. Campbell, F.R.I.B.A., was adopted. Working drawings and speci- fications were prepared by Mr. Campbell, and steps were then taken to obtain a suitable 334 Proceedings. block of stone. Inquiries were made at a number of quarries, and finally a block of Kairuru marble was selected by the Committee and approved by Mr. H. Hamilton. The block stands on a concrete base faced by four pieces of the same kind of marble, covering an area of 4 ft. 6 in. by 3 ft. 7 in. A bronze tablet is mounted on the main block, and has the following inscription in raised letters : — AUGUSTUS HAMILTON 1853-1913 Director of the Dominion Museum Wellington an eminent student of maori lore a lover of nature an earnest seeker after truth A bronze tablet is mounted in the marble base, and has the following inscription in raised letters : — KO TENEI PAKEHA KO HAMUTANA HE HOA TUTURU NO TE IWI MAORI, A HE TANGATA MANAAKI HOKI I NGA RAWA O MUA O TE MAORI, ME NGA KAUWHAU O NEHE. KoiA I TAPAIA AI TONA INGOA ko TUPAI TE AHORANGI ; te whatu o te whare WANANGA, ME TE KAI TIAKI O TE KETE ARONUI. This may be translated as — " This European Hamilton was a firm friend of the Maori people, a person who treasured their old-time works and ancient lore. Hence he was named Tupai te Ahorangi — the Core of the House of Learning, the Preserver of Occult Knowledge." The thanks of the Committee are tendered to Mr. R. W. Holmes, Engineer-in- Chief, and Mr. John Wood, District Engineer, Public Works Department ; to Mr. Elsdon Best ; to Mr. J. Campbell, Government Architect ; to Mr. G. Allport, Secretary for Marine ; and to Captain Bo lions, of the Government steamer " Hinemoa," for valuable services rendered. Through the actions of these gentlemen in saving expenses the Committee is enabled to hand over with this report an unexpended balance of £38 2s. 3d. The Committee recommends that this sum be invested by the New Zealand Institute, and that each year one half of the interest be added to the principal, and that the other half of the interest be devoted to a prize to be called the Hamilton Prize. The prize should be awarded from time to time by the New Zealand Institute to the author whose first scientific writings which shall be deemed worthy of the honour of the prize shall have appeared in the Transactions of the New Zealand Institute or other similar publication in New Zealand. The intention of the Committee is that the prize be restricted for competition among beginners in scientific research. The Committee has to report that this proposal is approved by the Hamilton family. Specifications, working drawings, and photographs of the monument are forwarded herewith. C. Monro Hector, Chairman. T. H. Easterfield. Wellington, 24th October, 1917. C. E. Adams, Secretary. New Zealand Mean Time.— A letter (20/12/17) from the Wellington Philosophical Society enclosing a printed report of a Committee of t?he Council of the Wellington Philosophical Society entitled " New Zealand Standard Time " was received. On the motion of Mr. Birks, seconded by Dr. J. Allan Thomson, it was resolved by nine votes to five, That the New Zealand Institute endorse the resolution of the Wellington Philosophical Society regarding the alteration of New Zealand mean time. Bird-protection.- — -A letter from the Royal Zoological and Acclimatisation Society of Victoria, Melbourne (15/10/17), was read and received. On the motion of Professor Kirk, seconded by Professor Thomas, it was resolved, That the Institute is in sympathy with all movements for the protection of Fifteenth Annual Meeting. 335 harmless birds, and is prepared to co-operate with the Forest and Bird Protection Society in this direction. Kapiti Island Sanctuary. — On the motion of Dr. Thomson, it was resolved, That Professor Kirk and Mr. Eliott, be a committee to visit and report on Kapiti Island at the next meeting, and that their expenses be reimbursed by the Institute. Other Correspondence.— Letters (d), (e), (/), (g), (h), (i), from the Internal Affairs Department, were read and received :■ — (d.) Protection of fur seals. (2/3/17.) (e.) Besolutions of the last meeting. (14/6/17.) (/.) Catalogue of New Zealand fishes. (14/3/17.) (g.) Housing library. (1/3/17.) (h.) Increase in grant to New Zealand Institute. (2/2/17.) (i.) Museum library. (1/2/17.) Dominion Museum.' — It was resolved, on the motion of Professor Kirk, to again draw the attention of the Government to the following resolution passed at last year's annual meeting: "That the attention of the Govern- ment be again called to the fact that the Dominion Museum collection, including many valuable records and objects that could by no possibility be replaced, are still housed in an old and highly combustible wooden building." Sounds National Park. — On the motion of Mr. Birks, seconded by Mr. Eliott, it was resolved, That the New Zealand Institute respectfully urges that the protection of seals in the Sounds National Park and Cascade Point be not delayed until the end of the war, but be dealt with by a clause in the Legislative Amendment Bill. Louvain University.- — A letter was received from M. P. Delannoy, Librarian of the University of Louvain, intimating that until a public depot for the reception of gift books for the University library restoration has been arranged for it will be better to keep any gifts from New Zealand in this country. Science Worthies.- — Letters were read from Mr. Henry Suter (8/2/17) and Major Thomas Broun (12/1/8) thanking the Institute for the congratu- latory letters (see p. 542, vol. 49). Dr. Thomson announced that he had visited the late Mr. Alexander McKay, who received the letter of the Institute during his last illness, and it was evident that the resolution of the Board had given him sincere pleasure. Societe d' 'Etudes Oceaniennes. — The Honorary Librarian mentioned that he had received publications of this society, and on his motion, seconded by Mr. G. M. Thomson, it was resolved, That the congratulations of the New Zealand Institute be accorded to the Societe d'Etudes Oceaniennes on its foundation, and on the publication of its bulletin. Deaths of Honorary Members. — The Honorary Librarian read a post- card announcing the death of Dr. S. Berggren, at Lund, which, in 'addition to the three mentioned in the President's address — viz., Bev. 0. Pickard- Cambridge, Bichard Lydekker, and George Massee — makes four vacancies in the roll of honorary members to be filled. 336 Proceedings. Amendment of Regulation. — On the motion of Professor Kirk, seconded by Dr. Cockayne, it was resolved, That regulation 5 (a) (1) be amended to read as follows : — :{ (a.) The publications of the Institute shall consist of' — (1) Such current abstract of the proceedings of the societies for the time being incorporated with the Institute as the Board of Governors deems desirable." New Zealand Journal of Science and Technology.' — Dr. Thomson laid on the table the first number of this Journal. He promised to communicate with the Secretaries of societies regarding the printing in the Journal of matter suitable suitable for the Journal and not for the Transactions of the Institute. Proposed Department of Scientific Affairs. — Mr. G. M. Thomson with- drew his motion regarding the establishment of a Department of Scientific Affairs (see Trans. N.Z. Inst., vol. 49, p. 542). Election of Officers. — The following officers for the ensuing year were elected : President, Dr. L. Cockayne, F.R.S. ; Hon. Editors, Drs. L. Cockayne and C. A. Cotton ; Hon. Treasurer, Mr. C. A. Ewen ; Hon. Secretary, Mr. B. C. Aston, F.I.C. ; Hon. Librarian, Dr. J. Allan Thomson. Publication Committee. — Professor Kirk, Drs. Cockayne, Cotton, and Thomson, Messrs. Aston and Hogben. Library Committee.- — Drs. Cockayne and Cotton and the Hon. Librarian. Research Grant Committee.- — Professor Easterfield, Messrs. Hogben and Aston. Hector Award Committee—Professor Easterfield (convener), Drs. Chilton, Cockayne, and Marshall. Date and Place of the next Annual Meeting. ■ — It was resolved, That the next annual meeting be held at Wellington on the 17th January, 1919. Travelling-expenses. — It was resolved, on the motion of Dr. Thomson, That the travelling-expenses of members of the Board to this meeting be paid by the Institute. Votes of Thanks to the retiring President for the able manner in which he had carried out the duties of his office for the past two years, and to the other officers, were unanimously carried. The Honorary Librarian desired to specially acknowledge the assistance he had received from Mr. McDonald in the library during the year. The meeting adjourned until the following day. The meeting resumed its sitting on Wednesday, the 30th January, 1918, at 9 a.m. Present : Professors Benham, President (in the chair), Thomas, Segar, Kirk, Drs. Cockayne, Hilgendorf, Thomson, Messrs. Aston, Birks, Ewen, Eliott, Hill, Hogben, Parr, and G. M. Thomson. President's Address.' — The following motions arising out of the sug- gestions contained in the President's address were brought forward by Dr. Hilgendorf : — Compliance of Incorporated Societies with Regulations. —On the motion of Dr. Hilgendorf, seconded by Professor Segar, it was resolved, That in Fifteenth Annual Meeting. 337 accordance with the President's suggestion the Treasurer be asked to examine the balance-sheets of the incorporated societies, and to report annually as to the compliance of incorporated societies with Regulation No. 3. Publication of the Minutes of the Annual Meeting.— On the motion of Dr. Hilgendorf, seconded by Mr. G. M. Thomson, it was resolved, That it be suggested to the Publication Committee that the report of the annual meeting of the Institute be printed and circulated to the affiliated Institutes as soon as possible after the meeting, as well as being incorporated in the Transactions in due course. f Establishment of an Endowment Fund. — Dr. Thomson, who previously at the meeting had given notice of his intention, now moved that an Endow- ment Fund be set up, the interest of which may be spent in any year for any purposes of the Institute, but the principal may not be spent. The motion was seconded by Professor Kirk, and carried. Reform, of the Institute. — The replies from the incorporated societies which had been received in answer to Dr. Thomson's proposals were laid on the table. On the motion of Dr. Cockayne, seconded by Mr. Hill, it was resolved, That a Committee be set up to report at next meeting on the matter of Fellowship of the Institute ; and on the motion of Mr. Parr, seconded by Mr. Eliott, it was resolved, That Mr. Hogben, Dr. Thomson, and Dr. Cockayne (convener) be appointed a Committee to draw up a scheme and refer it to the incorporated societies. On the motion of Mr. Birks, seconded by Mr. Hill, it was resolved, That this Board express its appreciation to Dr. J. Allan Thomson of his action in bringing forward the proposals dealing with the constitution of the Institute. ^jflj Public Meeting of the Institute. — On the motion of Dr. J. Allan Thom- son, seconded by Mr. G. M. Thomson, it was resolved, That the Institute accept the invitation of the Philosophical Institute of Canterbury to hold a week of meetings in Christ-church in the autumn of 1919. Co-ordination of Science and Industry. — Further reports were received from the incorporated societies, and were laid on the table. Board of Science and Industry. — On the motion of Professor Kirk, seconded by Mr. Birks, it was resolved, That this meeting of the Board of Governors of the New Zealand Institute considers it an essential part of the scheme for scientific and industrial research that the Board should be a trust to administer public and other funds given for the purpose for which it is constituted, and that for the first five years its finance should not be sub- jected to any amendment by Parliament, although duly audited ; and that Mr. Hogben and Dr. Thomson be a committee to transmit this resolution to the Government, after consultation with the National Efficiency Board. Vote of Thanks to the New Zealand Institute's Scientific and Industrial Research Committee. — It was resolved, on the motion of Professor Thomas, seconded by Dr. Hilgendorf, That this meeting expresses its appreciation of the work of the New Zealand Institute's Scientific and Industrial Re- search Committee, under the chairmanship of Mr. George Hogben, and is indebted to it for its successful efforts to embody the opinion of the Committees in the respective centres of New Zealand. Census of Industries. — On the motion of Mr. Hogben, seconded by Mr. G. M. Thomson, it was resolved, That a Committee be set up to co-operate 338 Proceedings . with the Director of the Dominion Museum in making a preliminary census of matters connected with scientific and industrial research. It was resolved that the following be the Committee, with the power to add to their number : Dr. Cockayne, Messrs. Hogben, Aston, Kirk, and Parry. It was resolved to leave the arrangements for carrying on propaganda in connection with science and industry to the same Committee. Confirmation of Minutes. — It was left to the Publication Committee, on Friday, the 1st February, 1918, to confirm the minutes of the annual meeting and to decide whether it was desirable to publish Appendices A, B, and C to the annual report. ADDRESS OF 1HE PRESIDENT. The following is the presidential address delivered at the annual meeting of the Board of Governors of the New Zealand Institute, at Wellington, on the 29th January, 1918, by Professor W. B. Benham, F.R.S. :— Gentlemen, — My thanks are due to you for doing me the honour of re-electing me to the Presidency of the Institute for a second year — a year that has been marked by the great activity of the Standing Committee in relation to the important work of endeavouring to draw up a scheme for the correlation of science and industry, to which I will refer later. Too little attention, 1 think, has been paid in past times to those of our own men of science who have passed away. Recently my attention was called to the fact that no memoir, no obituary notice even, is to be found in our Transactions of some who have done good service, especially to natural science, in New Zealand. Thus the work of Colenso and of Parker, to mention but two, is not recorded in our volumes. I think this should be rectified in the future, and that one of our officers, or some one else, should, while it is yet time, get together the salient facts of the life-history of those who are at present working, so that their contributions to the progress of science in New Zea- land may receive due recognition. It would be a very laborious task to write a history of the gradual building-up of science in New Zealand at the present time, and I am glad to see that Mr. G. M. Thomson is at present engaged in writing a series of articles on our naturalists in the Olago Witness. These will form a very valuable contribution to our history. It is, I think, a wise thing to recall to our minds from time to time the gradual steps by which each of our sciences has been built up, and the names of the men who have thus helped us : we are too much interested in the present-day problems to consider their history, and yet much of our present work is merely adding a brick or two to the edifice whose foundations have been laid in the past. Let us not think too greatly of the importance of that single brick, but rather think humbly of our own small contributions. I had intended to refer to some of the distinguished men of science who have passed away during the year, but 1 find my address already too long. Two of our honorary members are included in this list, while Lydekker, who died in 1916, should have been referred to in my last address. The Rev. Octavius Pkkard-Cambridge, F.R.S. , who was for fifty years vicar of Bloxworth, in Dorset, died in March, 1917, at the age of eighty-eight, and was one of the world's authorities on trap-door spiders, on which he contributed two papers to our Transactions describing some of our native species. Few naturalists of equal calibre are less revealed by their published work. He was a systematist, a describer and identifier of species, and though in this line of work no particularly brilliant dis- coveries are associated with his name, it is work requiring rather special gifts of careful observation, an absolutely necessary work on which biologists can build. George Massee, F.L.S., was aged sixty-seven when he died, in 1917. For twenty years he was head of the Crypytogamic Department at Kew, where he specialized on fungi. He published several systematic works on the group, and later turned his atten- tion to those which produce disease in plants, on which he published several descriptive works, useful alike to the botanist and the agriculturist. He contributed two papers to our Transactions on the fungus flora of New Zealand. He combined the skill of the artisl with the accuracy of observation of the scientist, many of his drawings which illustrate his work's being of great beauty. Fifteenth Annual Meeting. 339 It seems that the death of these two honorary members has been overlooked, as the affiliated societies were not notified of any vacancies in the list, of which there are now three.* It is unfortunate that the New Zealand Institute as a seientific body has no funds from which a contribution can be made to the memorial to the late Sir William Ramsay, F.R.S., Professor of Chemistry, and that we have to leave this and similar matters to the affiliated societies. It would certainly bring kudos to the Institute if its name figured amongst the subscribers to such a memorial as this. There will be presented to you a summary of the steps taken by the Standing Committee, with which was associated a number of gentlemen interested in industrial matters, to elaborate a scheme for the co-ordination of scientific and industrial research ; so that I need do little more than allude to it. There has been issued by the Govern- ment a report, signed by Mr. Hogben and Dr. Thomson, of the steps that have been taken in other parts of the Empire, and of certain schemes proposed by various bodies in New Zealand, with this object in view. Moreover, the final report of the above Committee has, 1 believe, been circulated. I trust that this important matter will not be allowed to rest, but that steps will be taken to persuade the Government of the very serious need for encouraging in every way, and especially by generous financial support, the prosecution of scientific research — not merely of research as applied to industry, but also, and primarily, of research in pure science, which, as we all know, is the foundation of the former. It has taken the scientific men of Britain over forty years to convince the British Government of the value of scientific research, for as long ago as 1870 a Royal Commission recommended the establishment of a State Council of Science presided over by a Minister of Science. As Professor Pope pointed out in an address delivered in October last, " If suitable provision had been made by the State for the pursuit of scientific research even twenty years ago, we should have been spared the horrors of the present conflict." It is only now, as the result of the urgent appeals of scientific men in Britain since the com- mencement of the war, that the British Government have estabbshed a Department of Scientific and Industrial Research, with an endowment of £1,000,000. Since the war began the public have awakened to the fact that all our present needs and comforts in orchnary fife are the outcome of discoveries made by scientific men in their laboratories, and several books (such as Gregory's Discovery : The Spirit and Service of Science, and, under Seward's editorship, the series of articles by Cambridge men of science issued under the title Science and the Nation) have been published putting the facts plainly before us, and impressing upon the public that' much of our backwardness in the British Empire is due to inadequate recognition, financial and social, of scientific research. We may hope that the British Government, at least, may thus become acquainted with the value of scientific discovery. Here in New Zealand there is need for a constant reminder of these facts : the Councils of our University colleges must be urged again and again to make proper pro- vision for carrying on researches in pure science, for no one can foresee what use may ultimately be made of some apparently trivial discovery in the laboratory ; and the more intimate association of industrialists with scientific men is needed so that they may be kept in touch with the progress of science. It is not enough, however, to draw up a scheme for the purpose of bringing this about : provision must be made for obtain- ing men to do research. At the recent meeting of the University Senate a letter was received from one of the Professors of Chemistry pointing out that it is better to provide adequate trained assistance to a professor, who would thus be relieved of some of the routine work of his chair and might then be able to devote time to research, than to award scholarships to graduates. This is certainly true ; and it is also necessary that greater encouragement should be given to our graduates to continue their studies in the University colleges, and to learn how to carry out research work. At present the only inducement held out to them is a National Research Scholarship, one of which is avail- able each year at each of the four colleges. But the Professorial Boards have repeatedly pointed out to the Education Department that the sum of £100 annually for two years is not sufficient to attract students unless they have independent means, for after spending four or five years in taking their Honours degree they naturally wish to begin earning a livelihood, and are therefore more readily attracted to the teaching profession, where a capable man or woman may obtain a salary of £150 to £180 as a teacher of science in a high school. These Research Scholarships should be made more valuable and increased in number ; and other inducements should be held out to our graduates, so that we may encourage those of our students who are capable of research to con- * The death of Dr. Berggren was also announced at the annual meeting. 340 Proceedings. tinue with us. If the colleges had the funds wherewith to provide adequate payment to trained assistants and demonstrators so that they would remain more than a year or two at the college and be teamed in research as well as in teaching, this would relieve the professors, and the college would be able to provide men and women capable of aiding our industrialists in solving their problems. But without a supply of such men any scheme for scientific and industrial research loses much of its point and value. And in the present scheme, although reference is made to increasing the number and value of these Research Scholarships, it does not seem to me that the Committee have sufficiently considered the mode of supply of requisite students. This is precisely what is being felt in Britain, where unfortunately many of the younger men of science have suffered death in this war instead of having been retained for the vastly important work of the future peace. Moreover, one reason why so many capable research students enter the teaching profession in Britain, as here, is that manufacturers have not seen fit. in most cases, to offer to trained researchers sufficient remuneration. Unless the professors are relieved of much of their routine work, and until it is recognized that the first duty of a professor is the promotion of research rather than, teaching, the award of scholarships will be in vain, and the introduction of graduates into industry will not lead to the developments necessary to carry out the ideal set out in the scheme for improving our industrial position in the world. In the covering letter signed by Mr. Hogben, Chairman of Committee, to the Chairman of the National Efficiency Board I notice an important proposal — viz., that some system of propaganda should be started. This is necessary, as the industrialists are no doubt in ignorance of what has been taking place, what steps are proposed, and, indeed, of the importance of the whole scheme. Almost too much stress seems to be laid in this report on research, and too little on the utilization of the scientific knowledge which has been accumulated by investigators in other countries. Hence the great importance of the propaganda hinted at by Mr. Hogben. What is so pre-eminently needed here, as in Britain, is a campaign to disseminate the scientific spirit throughout the community ; for unless we educate the entire people as to the value of the scientific method the object of this scheme will, I fear, be but temporarily and partially attained, and the movement so carefully elaborated by the Committee will soon collapse owing to the absence of any firm foundation in education. I do not know whether I ought to criticize the report of the Committee, but it seems to me that the method of election of the four members the Board is very elaborate, and the constitution of the local Advisory Boards too large, and there is no indication of where researches are to be conducted. That it does not require a great amount of organization to produce useful reseaich in regard to industry is seen by what has been done in South Australia. The South Australian Government Department of Chemistry, under Dr. Hargreaves, has issued nine bulletins dealing with possible new industries, and with industrial research on such matters as — Bonedust, its adulteration with phosphate rock ; alcohol as a source of power ; foaming of boiler waters ; grass-trees (Xanlhorrhoca), their economic pro- ducts ; potash, its economic sources ; wool-fat, its recovery and purification ; cream of tartar, its manufacture ; marine fibre, attempts to utilize. Another matter that will come before us is a report as to the proposed reform of the New Zealand Institute, which originated with Dr. J. Allan Thomson and the Wellington Philosophical Society. The proposals have been criticized by the affiliated societies chiefly in regard to the proposed new kind of membership and the change in name of the existing members to that of " associates." All the societies seem in favour of the establishment of Fellows, but if this be carried out we must guard the privilege of fellow- ship very jealously and put a definite limit on the number of Fellows to be elected annually, for there are not very many workers in science who are doing or have done work of such a high-class character as to entitle them to this distinction, and the number will soon become exhausted, so that unless a limit is placed on the number of Fellows it will become almost a matter of course that any worker would be nominated and the title would soon cease to have any honour attached to it. But the proposals have another aim, that of increasing the funds of the Institute, and I do not see that in this respect much is to be hoped for from the reform proposed. In my address at the last annual meeting of the Governors I referred to the Cawthron Institute. The report of the Commission appointed by the Trustees to draw up a scheme for the proper working of this Institute of research has now been presented to the Trustees, who are acting on the lines therein recommended. As the matter is one of very great importance for the future development of scientific work, it may be desirable to put the gist of the report on record here. The Institute will be erected, when the war Fifteenth Annual Meeting. 341 is ended, close to the city of Nelson. The work will be scientific research into the pro- blems of agriculture, particularly as affecting the growing of fruit, as this is the leading feature of the provincial district. It is hoped that agricultural problems of all kinds will in the future be studied — diseases of trees, improvement in culture, the chemistry and physics of the soil, the development of forest land, &c. ; and in time the work may be extended in other directions. Hitherto, as we are aware, no institution in New Zealand has been wholly or even mainly given up to scientific research, but theCawthron Institute will be equipped, financed, and organized for this purpose alone. The sum of money at the disposal of the Trustees is about £200,000, and the Trustees, who are for the most part business men, are determined that the annual expenses shall not exceed the income from the principal. Interest is accumulating, and from this it is proposed to erect the necessary buildings after the Director has been appointed and in consultation with him. The site has already been purchased and surveyed ; a caretaker has been appointed and is now looking after the orchard on the property. The Institute will be governed, under the Trustees, by an Advisory Board acting with the Director. On the Advisory Board the following bodies will be represented: the Cawthron Trustees, the Board of Agriculture, the Nelson Institute, the Board of Studies of the New Zealand University, and the Governors of the New Zealand Institute. Whether any formal intimation* to this effect has been received by our Secretary I do not know, but according to the report of the Commission we ought to nominate our representatives at this meeting. As a Director it is hoped to obtain a first-class chemist from England who has had experience of agricultural problems, but is not likely that he will be appointed until the war is over. When fully staffed it is intended that plant -physiology and plant- pathology, economic zoology and geology will be represented — but that will be in the future ; at the outset the Director will be assisted by a plant-pathologist and an orchardist, to whom adequate salaries will be paid. Provision will be made for the award of scholarships as follows : (a) A Nelson Scholarship to allow boys and girls to equip themselves at a University college to become students of the Institute ; (b) a Cawthron Scholarship to encourage brilhant scientific graduates to continue their work at the Institute ; (c) a Cawthron Fellowship of suffi- cient value to retain the services of such scholars and other students ; (d) an Industrial Fellowship which may be established by any body of industrialists who desires any special researches undertaken and who will pay the salary of this Fellow ; (e) an annual Cawthron Lectureship, the first holder of which is Professor Easterfield, who has already given the lecture. Of these scholarships it was suggested that the first should be awarded at once, but no proposal reached the Senate at its recent meeting ; the others not till the Institute is in full working -order. Every encouragement will be given to students pro- perly qualified to pursue research in agricultural matters, and it is hoped that in the future a constant stream of graduates who have received training in the fundamental sciences will be attracted by these scholarships and fellowships, and that from them will eventually be supplied expert teachers in agricultural subjects. It is important to notice that the Institute is quite independent of Government control. Some time during the year I noted a suggestion, made either in Parliament or in the Press, that all topographical features that have at present Austrian or German names should have these names changed. To me, and I suppose to most other scientific men and intelligent men generally, this appears to be not only a ridiculous proposal but one that is highly undesirable. The names of many mountains in the Alps and those of some of the glaciers would thus be altered, and, if this were done, books of travel in New Zealand, of mountain-climbing, maps, and other documents, would in the future be unintelligible. The Franz -Josef Glacier, for instance, is mentioned in books on geography and geology for certain peculiar features, and to alter its name on the ground that at present we are at war with Austria would render all such references meaningless. If there is any proposal of the kind on foot I think that this Institute should enter a strong protest against it, and obtain the support not only of the affiliated societies, but of associations of all kinds, such as the University colleges, professors, the Alpine Club, tourists, &c. In my last address I referred to the need of taking steps to protect the interesting rock shelters in Otago and Canterbury on the walls of which are paintings executed by the early inhabitants of New Zealand. I suggested that a committee should be set up, but I do not know that anything further was done. I understand that the matter is to be brought forward at the meeting of the Board of Science and Art ; but it seems to me distinctly the province of this Institute to persuade the Government to take some action to protect these interesting records. * Note by Hon. Secretary. — -No intimation has been received. 342 Proceedings. There remain one or two suggestions that have occurred to me in regard to the annual volume. One is that the report of our annual meeting should be published as soon as possible after it has been held. In the case of the affiliated societies the report of their annual meeting is issued to members very shortly after that meeting, but in the case of the meeting of the Governors it is, as you are aware, delayed till the volume of Transactions is issued, and it happened that this year I did not see the volume till early in January. I do not see why the report should not be published (with a separate paging, if necessary in roman numerals) within a month of our meeting, and circulated to every member of the Institute. I believe more interest would be taken in this meeting if this were done. At present the pagination of this report is continuous with that of the scientific transactions, but if roman numerals were used for this report and all that succeeds it in the volume there would be no difficulty in binding up this report with the rest of the volume. Why should the proceedings of the various societies be printed in the volume at all ? Nowadays they consist almost wholly of a list of the new members elected at each meeting, with the title of the addresses delivered or papers read. Formerly some epitome was given of what took place at these meetings, and that had its interest; but the present bare record can have no interest for any one. It is true that an abstract of the annual report is given, and this is the only part of the Proceedings that has any interest whatever to members of the Institute at large. Professor Kirk at the last meeting gave a notice of motion allowing the Board of Governors some discretion in this direction, and I hope he will move this motion to-day. I would suggest that the Publication Committee consider these two matters. A third matter has occurred to me — viz., whether the Treasurer of the New Zealand Institute examines the balance-sheets of the affiliated societies and ascertains whether they comply with the regulations under the Act of 1903 — as to the number of members, and the subscription annually paid towards the promotion of art, science, or other branch of knowledge ; and as to the expenditure in support of a library or museum. At our last meeting it was resolved to urge the Government to take immediate steps to form a scientific and technological library. Has anything been done in this direction ? No mention of the need of such a library occurs in the report of the Com- mittee on scientific and industrial research, yet surely before any work of value can be carried out it is necessary that the researchers should have access to what has already been done. By "library " I do not mean a building ; but there ought to be undertaken the making and printing of a catalogue of all books on science and technology — and the latter should perhaps be listed first — which are in the various Government Depart- ments, in the General Assembly library, in all University colleges, the Institutes, and Museums. No such comprehensive catalogue exists here as there is, for instance, in Victoria. Though it is true that a printed catalogue soon gets out of date, yet it does serve a very useful purpose, and additional leaflets could be added annually. For we must not overlook the fact that many, perhaps most, of the problems that may present themselves to the manufacturers in the Dominion, such as the utilization of by-products, the improvement in methods of manufacture, and so forth, have already been met in other parts of the world as a result of research : there is a store of scientific knowledge which is no doubt unknown to most of our industrialists, but which would be of great service to them, for it is only in a few cases that the problems are of such a peculiar character in New Zealand that special research is needed. I trust, therefore, that the Institute will take steps to carry into effect that resolution at an early date. It seems to me that at our annual meeting many resolutions are proposed and carried which are mere pious resolutions, such as are supposed to be made on New Year's Day, and nothing comes of them. Wellington Philosophical Society. 343 WELLINGTON PHILOSOPHICAL SOCIETY. Eight general meetings of the society (including the annual meeting) were held during the year 1917, at which the following papers and addresses were read :■ — (25th April) " Fly and Mosquito Larvicides," by Professor H. B. Kirk ; tw Perpetual Calendars." by Professor D. M. Y. Sommerville : (23rd May) "'Proportional Representation — a New Zealand Experience," by the President, Mr. G. Hogben : (27th June) " The Development of Hydro-electric Power in Canterbury," by Mr. L. Birks : (25th July) " The Outline of New Zealand.'" by Dr. C. A. Cotton ; " An Experiment in the Teaching of Fundamental Ideas in Geometry," by Miss P. Myers : (22nd August) " Hydro-electric Development of Power in Tasmania," by Mr. H. D. Cook : (26th September) " Crystal Analysis by means of X Rays," by Professor H. Clark : (24th October) " Further Notes on New Zealand Bird-song," by Mr. J. C. Andersen ; " The Botanical Districts of New Zea- land." by Dr. L. Cockayne : " Notes on New Zealand Floristic Botany," by Dr. L. Cockavne : (12th December) " Descriptions of New Zealand Lepidoptera," by Mr. E. Meyrick (communicated by Mr. G. V. Hudson) ; "* Is Earth-rotation the Cause of the Ocean Currents," by Mr. A. W. Burrell (communicated by Dr. C. E. Adams) ; '' A Note on the Young of Astraea heliotropium (Martyn)," by Miss M. K. Mestayer (communicated by Mr. R. L. Mestayer) ; " The Star Test for Telescopic Mirrors/' by Mr. T. Allison (communicated by Dr. C. E. Adams) ; " Comparisons between the Tidal Predictions and Actuality at the Ports of Auckland and Welling- ton," by Dr. C. E. Adams ; " Harmonic Analysis of Tidal Observations," by Dr. C. E. Adams ; " Prediction of Tides," by Dr. C. E. Adams ; " Notes on East Coast Earthquakes, 1914-1917," by Mr. G. Hogben ; " Physio- graphy and Agriculture of the Coastal District of Western Wellington," by Mr. A. H. Cockayne and Dr. C. A. Cotton : " Evidence of Warping on the Eastern Side of the Port Nicholson Depression," by Dr. C. A. Cotton ; " The Physiography of Rough Ridge, Otago," by Dr. C. A. Cotton. At the annual general meeting (24th October) the annual report and balance-sheet were adopted. Abstract of Annual Report. New Zealand Standard or Mean Time. — The Council forwarded to the Government a report drawn up by a committee giving reasons why New Zealand mean time should be altered so as to be exactly twelve hours in advance of Greenwich civil mean time. The Government replied that on account of the war it could not see its way to take any action at present. Printed copies of the report have been distributed to the other affiliated societies and to other bodies interested, and the matter will not be lost sight of. The proposal originated in a resolution passed by the ( louncil on the 30th November. IDlli, following the reading of a paper on " Daylight-saving " before the society by .Mr. C. W. Adams. The reform was also supported by the National Efficiency Board. (leant for Research. — Advice was received from the New Zealand Institute that a portion of the £2"><> voted by Parliament for research had no! been applied for. and applications for grants therefrom were invited. < >n the recommendation of the Council, grants in aid of out-of-pocket expenses were made in the following cases : (1) £50 to Messrs. W. S. La Trobe and C. E. Adams for a tide-predicting machine, and (2) £25 to Professor H. B. Kirk for an investigation of methods of killing mosquitoes and larvae. Science and Industry Committee. — On the 26th July, L916, a committee was appointed by the society to report on the organization of scientific and industrial research and the study of science within New Zealand. 344 Proceedings. The committee held twelve meetings, and its final report was adopted by the society at its September meeting, and was forwarded to the New Zealand Institute for con- sideration. The report will be printed at the end of a parliamentary paper dealing with the question of the relation between science and industry throughout the Empire. Tide-gauges at Outlying Islands of New Zealand.— The Council urged on the Govern- ment the importance of establishing tide-gauges at the outlying islands of New Zealand, in order that further investigations of the tides of the Pacific might be made. The Government has deferred consideration of the matter until after the war. Proposed Rnii < if the New Zealand Institute. — The New Zealand Institute having forwarded Dr. Thomson's proposals for the reform of the Institute, a report by the Council on these proposals was sent to the other incorporated societies, and replies fully discussing it have been received from the Philosophical Institute of Canterbury, the Otago Institute, the Auckland Institute, and the Manawatu Philosophical Society. Technical Library. — The Council endorsed a resolution of the Science and Industry Committee urging the importance of a technical library, and forwarded the resolution to the New Zealand Institute for transmission to the Government for its favourable consideration and action. Journal of Science. — -A proposal made by the Minister of Internal Affairs for the establishment of a Journal of Science was considered, and the following resolution was adopted and endorsed by the Council : " The Technological Section of the Wellington Philosophical Society is of opinion that the publication of a Dominion Journal of Science, open to contributions from all sources, is a necessity and satisfies a long-felt want, and hereby offers its heartiest congratulations to the Minister of Internal Affairs upon his action in founding and establishing the Journal, but respectfully suggests that the title be altered to read, ' The New Zealand Journal of Science and Technology,' thereby extending the scope of the Journal." The Minister has agreed to the change of title. Hamilton Memorial. — The report of the Hamilton Memorial Committee has been received (see pp. 333-34). Jubilee of the Society. — The 13th November, 1017, is the fiftieth anniversary of the foundation of the society. The Council considers that owing to the present state of war it is not desirable to take any steps to celebrate the jubilee this year. Membership. — Since the annual meeting of 1916 twelve members have been elected, one member has become a life member under Rule 26, one life member (Mr. R. Coupland Harding) and one ordinary member have died, while one member has been killed in action. Six members have resigned their membership. The roll now stands at nine life member's, twenty-three members on active service or in camp in New Zealand, and 146 ordinary members, making a total of 178 members. The following officers and Council were elected for the year 1918 : President - G. Hogben, C.M.G., M.A., F.G.S. Vice-Presidents — R. W. Holmes, M.Inst.C.E. ; C. E. Adams, D.Sc, F.R.A.S. Council — C. A. Cotton, D.Sc, F.G.S. ; T. H. Easterfield, M.A., Ph.D. ; F. W. Furkert, A.M.Inst.C.E. ; C. Monro Hector, M.D., B.Sc, F.R.A.S. ; J. Henderson, M.A., D.Sc, B.Sc (Eng.) ; S. H. Jenkinson ; H. B. Kirk, M.A. ; W. S. La Trobe, M.A. ; E. Parry, B.Sc, M.I.E.E., A.M.Inst.C.E. ; D. M. Y. Sommerville, M.A., D.Sc, F.R.S.E. Secretary and Treasurer — J. Allan Thomson, M.A., D.Sc, F.G.S. Auditor --E. R. Dymock, F.I.A.N.Z. Representatives on the New Zealand Institute — G. Hogben, C.M.G., M.A., F.G.S. ; H. B. Kirk, M.A. ASTRONOMICAL SECTION. The following papers have been read before the section during the year 1917: — (4th October) " Long-period Variables," by C. E. Adams, D.Sc. : (1st November) " The Hartness Turret Telescope," by C. E. Adams, D.Sc; "An Easy Method of Night Marching by the Stars," by G. Hogben, F.G.S. : (6th June) Presidential Address, " The Importance of Pure Science," by W. S. La Trobe, M.A. ; " Description of a Planisphere," by D. M. Y. Sommerville,. M.A. ; "Comet a 1917 Mellish," by C. E. Adams, "D.Sc. : (4th July) " An Appreciation of the Early Astronomers," by the Rev. B. Dudley, F.R.A.S. ; " A Homogram for Transit Star Factors," by C. E. Adams, D.Sc. : (4th August) " The Principle of Relativity," by D. M. Y. Sommerville, M.A. : (5th Sep- tember) " The Nebulae," by A. C. Gifford, M.A., F.R.A.S. Wellington Philosophical Society. 345 Committet and Officers for IMS. — Chairman. — D. M. V. Sommerville, M.A., D.Se. Vice-Chairmen — W. S. La Trobe, M.A. ; E. Parry, B.Sc, M.I.E.E., A.M. Inst. C.E. Committee— C. P. Powles; H. Clark, M.S.. Ph.D.; A. C. Gifford, M.A., F.R.A.S. : C. Monro Hector, M.D., B.Sc, F.R.A.S. ; G. S. Hooper. Director and Curator of Instruments- C. E. Adams, D.Se., F.R.A.S. Hon. Treasurer C. I'. Powles. U<>n. Secretary ('. G. < >. Berry. TECHNOLOGICAL SECTION. The following papers have been read during 1917 : — (9th May) " Irrigation in New Zealand," by F. W. Furkert, A.M.Inst.C.E. : (13th June) "Smelting of [ronsand at Onehunga," by J. M. Chambers (communicated by E. Parry) ; '" Experiments on the Smelting of Ironsand," by J. E. L. Cull, B.Sc. : (11th July) ''Losses through Evapora- tion and Percolation from Irrigation-works," by F. W. Furkert, A.M.Inst.C.E. ; "Dia- grams collating Tables of Safe Loads on Stanchions," by W. S. La Trobe, M.A. ; " Friction of Water in Pipes," by E. Parry, B.Sc. : (8th August) " Convenient Diagrams for the Design of Remforced-concrete Beams," by W. S. La Trobe, M.A. : (12th Sep- tember) " Datum Levels," by Dr. C. E. Adams ; " Economic Aspects of the Greensands of New Zealand," by Dr. J. A. Thomson : (10th October) " Corrosion by Mine-water," by Professor Easterfield ; " Crystal Analysis by means of X Rays," by Professor H. Clark: '" Failure of High-tension Insulators," by E. Parry, B.Sc; "Some Toi'que Diagrams." by S. H. Jenkinson. The officers for the year 191S were elected as follows : Chairman — S. H. Jenkinson. Vice-Chair turn — E. Parry, B.Sc. ; W. S. La Trobe, M.A. Committee — R. W. Holmes, M.Inst. C.E. ; Dr. Maclaurin ; H. Sladden, Member of Board of Surveyors ; Professor H. Clark; F. W. Furkert, A.M.Inst.C.E. Secretary— A. J. Patterson. GEOLOGICAL SECTION. The following papers have been read during 1917 : C. A. Cotton. "' Across America by the Santa Fe Route," and " The Age and Correlation of the Covering Strata in Central and Eastern Otago " ; J. A. Thomson, " The So-called Drift Formation of Hawera," " The Relative Age of the North Otago and South Canterbury Limestones," and " The Geology of the Clarence Valley between the Bluff and the Herring River " ; P. G. Morgan, " Potash in New Zealand " ; J. Henderson, " The Physiography of that Part of the Waikato Valley near Maungatautari," and " The Geology of the Waitomo Caves " ; J. A. Bartrum, " Some Concretions in Recent Sediments in Auckland Har- bour " ; W. Donovan, " Some Analysis of New Zealand Coals " ; E. K. Lomas, " The Teaching of Geography." The section is indebted to these members for their work, and for thus maintaining the interest in the Geological Section. At the conclusion of Mr. Lomas's paper on " The Teaching of Geography " the following motion was carried : ' That the Council be requested to urge upon the Government the importance botli from the educational and economic standpoint of the more extensive publication of the meteorological observations for a larger number of stations in New Zealand." Officers and Committee for 1918. — Chairman — J. Henderson, M.A., D.Se. Vice- Chairman—E. K. Lomas, M.A., M.Sc. Committee— Q. Hogben, C.M.G., M.A., F.G.S. ; R. W. Holmes, M.Inst.C.E. ; P. G. Morgan, M.A., F.G.S. ; J. A. Thomson, M.A., D.Se, F.G.S. ; G. Uttlev. M.A., M.Sc.. F.G.S. Hon. Secretary— C. A. Cotton. D.Se.. F.G.S. 346 Proceedings. AUCKLAND INSTITUTE. Seven meetings were held during the year 1917, at which the following lectures and papers were read: — (11th June) 'Berlin, Bagdad, and the Balkans — Germany's Eastern Ambitions," by Professor J. P. Grossmann : (9th July) "The Kermadec Islands, their Plant and Bird Life,'* by Mr. W. R. B. Oliver : (6th August) " Some Present Aspects of the War,*' by the Rev. W. G. Monckton : (3rd September) '" Natural Sources of Power, their Importance to New Zealand," by Mr. F. E. Powell. C.E. : (1st October) " Heredity," by Professor A. P. W. Thomas, F.L.S. : (19th November) " The Civic Spirit of Roman Architecture," by Mr. T. G. Price : (11th December) "A New Species of Hy pole-pis," by Mr. H. Carse ; "The Extra- ordinary Rainfall of 1915-1916," by Mr. EL B. Devereux ; "On the Dis- tribution of the Pentatonic Scale in Britain," by Professor J. C. Johnson ; " On the Sporophyte of Rhipogonum scandens," by Miss A. C. Tizard (com- municated by Professor J. C. Johnson) ; ' Descriptions of New Native Flowering-plants," by Mr. D. Petrie. At the annual meeting (25th February, 1918) the annual report and audited financial statement was read to the meeting, and ordered to be printed and distributed among the members. Abstract. The report which the Council now presents to the members marks the completion of the fiftieth year of the existence of the society. At the conclusion of such a period it is natural that the governing bod}', while paying full attention to the requirements of the present, should also concern itself with the demands of the future ; or, in other winds, take into consideration the subsequent aims and development of the Institute and Museum. The first part of the report will therefore contain the customary account of the activities of the society during the past year, while in the second will be given a brief statement of those views regarding future development that have been discussed at various meetings of the Council, and also (lie final conclusions that have been arrived at. Members. — Mainly through a special canvass undertaken by the Hon. E. Mitchelson and another member of the Council, no less than eighty-eight new members have been elected during the year. On the other hand, twenty-nine names have been withdrawn— fourteen from death, ten from resignation, and five from non-payment of subscription for more than two consecutive years. The net gain is thus fifty-nine, the number on the roll at the present time being 450. Finance. — Full information respecting the financial position of the society is given in the balance-sheets appended to the report ; hut the following brief synopsis may be useful. The total revenue of the Working Account, after deducting the balance in hand at the beginning of the year, has been £1,827 16s. 7d. This compares favourably with the amount for the previous year, which was £1,741 12s. (id., showing an increase of £86 4s. Id. Examining the various items, it will be seen that the members' subscrip- tions have yielded £420, being an advance of t46 4s. on last year's figures. The receipts from the .Museum Endowment, consisting of rents and interest, have amounted to £713 12s. lid., evidencing a slight decrease. On the other hand, the receipts from the invested funds of the Costley Bequest, which have yielded £453 18s. Id., are slightly larger than last year's amount. The remaining items call for no special remark. The expenditure has amounted to £1,763 lis. 4y the Council bo '(insider the co-ordination of science and industry, whose lirst report appeared last year, lias continued its labours during the present session, and has prepared a second communication. This, together with reports from other committees set up by the various branches of the New Zealand Institute, has been placed before a general committee of the Institute sitting in Wel- lington, which, it is understood, will shortly forward a full statement of its views to the Government. Museum. With the exception of a short period necessarily devoted to cleaning and rearrangement, the Museum has been open to the public daily throughout the year. The attendance has been excellent, although not quite equal to that of the three years I !t 1 4 to 1916, the total number of visitors being 87,350. Considerable progress has been made in the Museum during the year. The numerous recent additions to the Maori collections have rendered it necessary to rearrange a large part of the contents of the .Maori Hall. The work is not yet com- pleted, but sufficient has been done to make the collections much more intelligible to visitors, and more readily inspected. A plate-glass show-case has been provided for the fine series of taiahas, battle-axes, &c, in the possession of the Museum. These are now much more worthily exhibited, and the space they formerly occupied has supplied accommodation for other articles. As detailed in last year's report, the completion of the new mineral-room, .and the transfer to it of many specimens formerly exhibited in the gallery of the main hall, will provide some additional space for the representation of the New Zealand fauna. It is intended to utilize the table-cases on the south side of the gallery for the reception of the New Zealand shells, and a considerable amount of preliminary work has been done. such as the cleaning and repainting of the cases, the preparation bf the trays and tablets for the specimens, cataloguing, soiling. &c. It is hoped to commence the actual arrangement in a short time. In the taxidermist's department Mr. Griffin has nearly completed a very realistic group illustrating the breeding-habits of the black-fronted tern, one of the most graceful of New Zealand birds. The group, which has cost a large amount of patient work and preparation, is of an entirely different character to those already exhibited, and will be generally admired. The additions and donations received during the year have been numerous and valuable, as will be seen from the list appended to the report, but only the more important can be mentioned here. In the ethnographical department special reference should 1).' made to three historical bone meres, purchased and presented to the Museum by the Hon. A. M. Myers, Mr. Henry Brett, and Mr. R. H. Abbott. Two of these were formerly the property of the celebrated chieftain Rewi Maniapoto, whose name will always be remembered in connection with the Maori War and the defence of < hakau against our troops. The third belonged to the well-known Urewera warrior Hauwai. Mr. H. E. Partridge has donated ten plaster bas-reliefs of the busts of Maoris and Hawaiians, modelled from life by the well-known sculptor Allan Hutchinson. These will be most useful to the Museum when attempts are made to prepare modelled groups of Maoris engaged in their old-time avocations. Another valuable addition consists of ten limestone slabs bearing pre-Maori rock- paintings or pictographs, obtained by Dr. Elmore, an American scientist, from certain rock shelters in North Otago. The cost of excavating the slabs, together with others intended for the Otago Museum, was borne by the Otago and Auckland Institutes. Although these pictographs, together with others in Canterbury, have been known for many years, they have not attracted the notice that they certainly deserve. Single articles of note consist of a remarkably tine and delicately carved charm, or mauri, presented by Mr. F. R. Hutchinson : a large and beautifully polished stone adze, contributed by Mr. R. W. Duder ; and one of the rare neck-ornaments carved from the teeth of the sperm-whale, donated by Mr. Percy Monk. In last year's report the Council stated that arrangements had been made with the Gizeh Museum. Cairo, for a first instalment of Egyptian antiquities. The collection has since arrived, and has- been placed in a special show -case. It contains about a hundred examples, the most interesting being a series of vases, bowls, libation-vessels, &c, discovered by Dr. Quibell in an 11th dynasty tomb at Sakkarah, near Memphis. The collection forms a very welcome acquisition, arid it is hoped that arrangements may be made for other consignments. Mr. Henry Shaw, whose previous gifts of Japanese porcelain, bronzes, ivories, &c, are still fresh in the memory of the Institute, has made an additional presentation of Satsuma and Kioto porcelain, comprising more than fifty articles, together with a few temporarily lent. A special case has been provided, in which the specimens are now exhibited. The thanks of the Museum have been voted to Mr. Shaw for this renewed instance of libera lit v. 348 Proceedings. Dr. C. J. Wood, Bishop of Melanesia, has presented a remarkably good outrigger canoe, 29 ft. in length, from the Island of Tikopia, in the eastern part of the Solomon Group. Dr. Wood had previously contributed two tine canoes of different types to the Museum, and his present gift is valuable as a help towards forming a comparative scries. In the natural-history department, although a considerable number of small additions have been received, no collections of any size have been added, apart from those obtained by the staff of the Museum. It is quite evident that in the future, so far as many classes of specimens are concerned, the .Museum must rely on the activities of its own officers, or on trained collectors engaged by it. Library. — The undoubted risk of loss through submarines, and the greatly increased charges for freight, insurance, &c, have compelled the Council to suspend the purchase of books for the present. It has been decided, however, to keep up the subscriptions to all 2iiagazincs and serial publications at present on the society's list. The Council has pleasure in acknowledging the donation by Mr. K. Logan of a copy of Rothschild's costly and magnificent work on "' Extinct Birds." Development of flu Museum and the Need for a New Site. — The summary just given of the work performed by the Institute during the year affords many evidences of progress and many proofs of the increasing Interest taken by the citizens in both the Museum. and library. But regularly increasing donations and additions, however gratify- ing they may be as proofs of public confidence and support, arc every year increasing the difficulty is housing the collections and exhibiting them to the public. They accentuate the one main fact hindering the development of the .Museum and the efforts of its guardians to place it on a higher level — want of room. And this want is not confined to one branch of the Museum, but exists in every department. In addition, it effectually prevents any expansion of the present aims of the institution. There are many activities usually associated with a well-ordered and progressive Museum that are excluded from the Auckland Museum through want of room. Much consideration has been given to the matter by the Council, and several meetings have been held. It soon became obvious that the question for decision was simply this: Can sufficient accommodation, with (\ue regard to future needs, be obtained on the present site : and, if not, what site is best adapted for the purpose ? Investiga- tion soon proved that the unbuilt-upon portion of the existing site, with its almost precipitous slope, was likely to j^rove both inconvenient and expensive, while it was not large enough for present requirements, to say nothing of future needs. Having arrived at the conclusion that the removal of the Museum from its present position was inevitable, it became necessary for the Council to search for a new locality. In doing this, it was recognized that the new Museum should occupy a central position, and should possess the fundamental advantages of room for future expansion, decreased risk of fire, and freedom from dust and smoke. Further, it was admitted that, as no public Museum in Australia or New Zealand has had to provide its own site, there was no reason why the Auckland Museum should be treated in a different manner. After an examination of those sites — by no means numerous — that complied with the conditions mentioned above, a meeting of the Council .was held to decide which was the most suitable. After full discussion, and after the reasons in favour of changing the site had again been reviewed, the following resolution was moved by the Hon. E. Mitchelson, seconded by Mr. C. J. Parr, M.P., and unanimously adopted: "That this Council is of opinion that the most suitable site upon which to erect a permanent Museum is that part of the Auckland Domain known as Observatory Hill : and that the Auck- land City Council be requested to assent to this proposition, with the view of asking Parliament for authority and power to carry out the project." This expression of the views of the Institute was placed before the City Council at a meeting held on the 7th February. It was supported by the Mayor and Deputy Mayor, who respectively proposed and seconded the following resolution, which was unanimously adopted: ■"That the request of the Council of the Auckland Institute and Museum for the permission of the Auckland City Council -to place a Museum building upon Observatory Hill, in the Auckland Domain, be granted, subject to the Council of the Institute promoting the necessary validating legislation. Further, the Council of the Institute to make provision for the City Council being represented on their body as follows: Mayor of Auckland ex officio member of the Council of the Institute, and two others to be nominated by the Auckland City Council." It is a satisfaction to the Council of the Institute to receive such a sympathetic assurance of co-operation from the City Council, and it is hoped that such friendly relations may long exist. The Council of the Institute has apjjroved of the terms prescribed by the City Council, and is taking steps to promote the necessary legislation as soon as practicable in order to enable the proposed new building to be erected within the Auckland Domain. Auckland Institute. 349 Election of Officers for 1918, -President— Mr. J. II. Gunson, Mayor of Auckland. Vice-Presidents Hon. E. Mitchelson ; Mr. C. J. Parr, C.M.G., M.P. Council -Professor C. W. Egerton, Mr. J. Kenderdine, Mr. T. W. Leys, Mr. E. V. Miller, Mr. T. Peacock, Mr. D. Petrie, Professor H. W. Segar. Professor A. P. W. Thomas, Mr. J. H. Upton, Mr. H. E. Vaile, Professor F. P. Worley. Trustees— Mr. T. Peacock, Mr. J. Reid, Professor A. P. W. Thomas, Mr. J. H. Upton, Mr. H. E. Vaile. Secretary and Curator — Mr. T. F. Cheeseman. Auditor- Mr. S. Gray. PHILOSOPHICAL INSTITUTE OF CANTERBURY. During the year 1917 nine meetings were held (including the annual general meeting, 5th December), and the following addresses and papers were presented : — (2nd May) " Some Questions of Efficiency," presidential address, by Mr. L. Birks (discussed, 6th June) : (1st August) " The Fly Nuisance and its Control," by Professor H. B. Kirk : (5th September) " Notes on the Susceptibility of New Zealand Timbers to the Attacks of the Borer,'" by Mr. R. Speight : :' On the Conformity of the Amuri and Weka Pass Limestones," by Messrs. R. Speight and L. J. Wild ; :' A Fossil Isopod belonging to the Fresh- water Genus Phreatoicus," by Dr. Charles Chilton ; ' A Collection of Insects from Cass," by Dr. F. W. Hilgendorf : (3rd October) " Science and Economics," by Dr. J. Hight : (7th November) " Note on a Record of an Earth epiake obtained from an Artesian Well," by Mr. L. P. Symes ; ' The Course of Land-values in Canterbury," by Mr. F. R. Callaghan : (21st November) " Some Poison Gases," by Dr. W. P. Evans : (5th December) " Some Glacial and Structural Features of the Hurunui Valley," by Mr. R. Speight ; " Revision of the New Zealand Cirripedia," by the late Captain L. S. Jennings ; " Studies in the New Zealand Species of the Genus Lycopodium : Part III, the Structure of the Prothallus and the Embryo," by the Rev. Dr. J. E. Holloway ; " Testing- High-tension Insulators," by Mr. L. Birks ; " On the Distribution of Senecio saxifragoides Hook. f. and its Relation to Senecio lagopus Raoul," by Pro- fessor A. Wall (communicated by Mr. R. Speight) ; " Further Observations on Soil-adsorption," by Mr. L. J. Wild. At the annual meeting the following officers were elected for 1918 : President- -Mr. W. H. Skinner. Vice-Presidents — Mr. L. Birks and Dr. C. C. Farr. Secretary — Mr. L. P. Symes. Treasurer Dr. Charles Chilton. Librarian— Mi. S. Page. Council — Dr. F. W. Hilgendorf, Dr. W. H. Symes, Mr. L. J. Wild, Mr. A. D. Dobson, Mr. W. G. Aldridge, and Mr. W. Martin. Representatives on the Board of Governors of the New Zealand Institute — Dr. F. W. Hilgendorf and Mr. L. Birks. Auditor— Mr. G. E. Way. Abstract of Annual Report. Members on Active Service. — The Council desires to record that the following members are now serving in the Empire's Forces: Drs. H. Acland and F. J. Borrie, Messrs. G. E. Arehey, J. W. Bird, F. M. Corkill, E. Kidson, ('. E. Foweraker, A. Fair- bairn, H. T. Ferrar, A. Taylor, G. T. Weston, F. S. Wilding, A. M. Wright, H. Rands, E. F. Stead. Obituary. — With great regret the Council records the death of Mr. H. P. Murray - Aynsley, a member for very many years ; and that Mr. P. 8. Nelson, M.Sc, and Mr. G. Maclndoe, B.E., were killed in action. 350 Proceedings. Co-ordination of Science and Industry. — This matter has received the constan attention of the Council. In April, by request of the local Commissioner of the National Efficiency Board, members of the Council waited on him and discussed various matters relative to national efficiency. A number of suggestions were made to the Commissioner, and several matters were referred to members of the Institute for report. Another matter which has engaged the attention of your Council is the proposal made by the Scientific and Industrial Research Committee of the New Zealand Institute, to recommend the establishment of a national Board of Science and Industry. The Council has criticized some features of the scheme and made suggestions with a view to its improvement. Your < louncil earnestly trusts that this proposal will materialize and that an institution of great national value will result. Government Research (Irani. — The sum of tl l(t allotted by the New Zealand Institute to members of this Institute was received in .March, and part has been paid over to grantees. Considerable progress has been made in the investigation of the phosphate rocks of Canterbury by Messrs. R, Speight and L. J. Wild. A paper on some of the results of their observations has been read before the Institute. Certain preliminary work has been done on the other investigations — viz., the deterioration of apples in cold storage, and the electrical prevention of frosting in orchards. Proposed Reform of the New Zealand Institute. — The Council has given very serious attention to certain proposals which have been received for the remodelling of the New Zealand Institute. The Council, while anxious that the position of the New Zealand Institute, both financial and otherwise, should be strengthened, has deprecated any action which it considers would injure the local societies or destroy the present repre- sentative nature of the governing body. OTAC40 INSTITUTE. During the year eight ordinary meetings of the Institute were held, at which there were read or received eleven papers embodying the results of original research. The titles of these papers, with the names of the authors, are as follows: — (12th June) 'On a Partially White Form of Puffinus griseus," by Mr. D. L. Poppelwell : ;t Notes on a Botanical Visit to Holly- ford Valley and Martin's Bay." by Messrs. D. L. Poppelwell and W. A. Thomson ; " Notes on a Botanical Excursion to Bunker's Island," by Mr. D. L. Poppelwell; "Notes on a Botanical Visit to Coll or Bench Island," by Mr. D. L. Poppelwell : (9th October) " On the Age of the Alpine Chain of Western Otago," by Professor J. Park, F.G.S. ; " On the Miocene (Oamaru Stone) Coral Reef," by Professor J. Park, F.G.S. ; "Descriptions of New Species of Lepidoptera," by Mr. Alfred Philpott (communicated) ; " On the Structure of Amphibola crenata,'n by Miss W. Farnie, M.A. (com- municated) ; ;' Notes on a Trematode from Amphibola crenata," by Miss W. Farnie, M.A. (communicated) ; ;' Notes on the Autecology of certain Plants of the Mineral Belt, Nelson," by Miss M. W. Betts, ~M.Sc. (com- municated) ; " The Origin of Serpentine," by Dr. W. N. Benson, F.G.S. The following addresses have also been delivered during the past ses- sion : ' The Position of Science in our Educational System " (presidential address), by Dr. J. K. II. Inglis ; " The Coming of the Earthworm to New Zealand," by Dr. W. B. Benham ; "The Rainbow Top," by Mr. T. B. Hamilton; "William James and Pragmatism," by Dr. F. W. Dunlop ; ' The Gyroscope and its Applications," by Dr. R. Jack ; " The Occurrence and Oeiiesis of Ore Deposits," by Professor J. Park ; and " A Chapter in Evolution," by Dr. W. P. Gowland. Otago I itst it tile. 351 At the annual meeting (4th December) the annual report was adopted, and the following officers were elected for 1918 : President — Professor R. Jack. Vice-Presidents Professor J. K. H. Inglis and Mr. G. M. Thomson. Hon. Secretary — Mr. E. J. Parr. Hon. Treasurer Mr. H. Brasch. Hon. Auditor Mr. J. W. Milnes. Council — Professors W. B. Benham, W. N. Benson, J. Park, and D. B. Waters, Dr. R. V. Fulton, Messrs. G. W. Howes and H. Mandeno. Representatives oh the Hoard of Governors of the New Zealand Institute Messrs. G. M. Thomson and E. J. Parr. Abstract of Annual Report. The attention of the Council during the year has been very largely centred upon the consideration of a proposal for the reform of the New Zealand Institute. The proposed scheme of reform, which originated in the first instance with the Director of the Dominion Museum, has been submitted by the New Zealand Institute to each of the affiliated societies for its careful consideration. At the present time it appears that when the scheme comes up for final consideration by the New Zealand Institute at its annual meeting in January it will be considerably restricted in its scope before its final adoption. As regards some of the more important features of the scheme, your Council has expressed itself as being in favour of the proposed appointment or election of Fellows of the Institute as a mark of distinction in recognition of scientific research work, and also of the jtroposal to hold public meetings of the New Zealand Institute in various centres in rotation, and is strongly of the opinion that an increased Government grant is urgently needed by the Institute in order that it may carry on its work. " It does not, however, see any necessity for altering the constitution of the Board of Governors of the Institute, nor for the establishment of an associate membership. At the request of the New Zealand Institute your Council has also eo-operated with the other affiliated societies in drawing up recommendations and suggestions to assist the Efficiency Board in drafting a scheme for the co-ordination of science and industry. Support was also given to the Wellington Philosophical Society in its endeavour to have New Zealand mean time made exactly twelve hours in advance of Greenwich mean time, instead of eleven hours and a half as at present. A sum of five guineas has been donated to the Sir William Ramsay Memorial Fund, which is to be used for improvements in the training of chemists for industrial work. e TECHNOLOGICAL BRAN( H . Five meetings were held during 1917, and the following papers and addresses were read: (22nd May) "Steam Generators," by Mr. R. A. McLintoek ; (19th June) " Fuels for Internal-combustion Engines," by Mr. J. B. Mason; (17th July) " Bridge- design on the New Zealand Railways," by Mr. F. J. Jones ; (21st August) " The Fir Hazard of Electrical Installations," by Mr. F. R, Shepherd; (Kith October) " Hydro- electrical- Power," by Mr. M. C. Henderson. At the meeting of the 16th October the annual report of the branch was read and adopted, and the following officers for 1918 were elected : Chairman, — Mr. J. B. Mason. Vice-Chairmen — Professors J. Park and D. B. Waters, and Mr. B. B. Hooper. Hon. Secretary — Mr. H. Brasch. Committee — Messrs. M. C. Henderson. F. J. .Jones, H. Mandeno, G. Simpson, and R. N. Vanes. ASTRONOMICAL BRANCH. Only one meeting was held during the year — that of the 23rd October; a paper on '" Astronomy in War-time " was read by .Mr. J. W. Milnes. The following officers for 1918 were elected at the same meeting : Chairman- Mr. R. Gilkison. Vice-Chairmen — Professors R. Jack, J. Park, and D. R. White. Hon. Secretary — Mr. J. W. Milnes. Committer — Dr. P. D. Cameron, and Messrs. H. Brasch, C. Frys, W. T. Neill, E. J. Parr, and W. S. Wilson. 352 Proceedings. HAWKE'S BAY PHILOSOPHICAL INSTITUTE. Eight meetings were held during 1917. and the following papers were read : (18th May) Cv Old Hawke's Bay— the Provincial Days," by W. Din- widdie ; (18th June) " The Marvels of Luminiferous Ether,"' by J- W. Poynton, S.M. ; (27th July) " The Development of Thought and Language, chiefly in regard to the Lower Animals," by T. Hyde ; (17th August) '• Bacon and" Shakespeare," by H. Hill, B.A.", F.G.S. ; (28th September) " Popular Bacteriology," by J. W. Poynton, S.M. ; (2nd November) " His- tory and Development of the Water-supply of the Taupo Plains," by H. Hill, B.A., F.G.S. ; (13th December) L' Milk as a Food," by E. G. Loten. At the annual meeting (13th December) the annual report was read and adopted, and the following officers for 1918 were elected : President— T. Hyde. Vice-President— W . A. Armour, M.A., M.Sc. Council— W. Din- widdle ; H. Hill, B.A., F.G.S. ; F. Hutchinson, jun. : W. Kerr, M.A. ; E. G. Loten ; T. C. Moore, M.D. Hon. Secretary and Treasurer — D. A. Strachan, M.A. Hon. Auditor — H. Hill, B.A., F.G.S. Hon. Lanternist— E. G. Loten. Representative— K. Hill, B.A., F.G S. MANAWATU PHILOSOPHICAL SOCIETY During the year eight general meetings were held, at which the following papers were read : ' The Frozen-meat Industry," by M. A. Eliott : " Pair- ing Relations of Matter in Animal and Vegetable Life," by D. Sinclair, C.E. ; ' Time, how it is found and kept," by C. T. Salmon, Assoc, in Eng., Canterbury College ; ' Bird-life in the Southern Islets . of New Zealand," by G. Thomas ; " Antarctic Exploration," by H. Hill, B.A., F.G.S. ; ' Economic Plants that should be imported into New Zealand," by J. W. Poynton, S.M. ; " Some Unconsidered Aspects of the War," by j'. W. Poynton, S.M. ; " Hydro-electricity," by A. J. Colquhoun, M.Sc. At the animal meeting the annual report and balance-sheet was adopted. Abstract of Annual Re^prt. During the year several matters not merely of local but of great general importance have occupied the attention of the Council. At their request the Government has agreed to extend the measures for the preservation of native birds to the outlying islets of Stewart Island, and has referred the matter to Dr. Thomson and Mr. Phillips Turner for suggestions as to the measures necessary to be taken, and' these gentlemen have issued a full report on the bird-life of the Dominion, a copy of which has been made for our library and is accessible to any member of the society. The Council has also given its warm support to the endeavour of Foxton to secure the preservation of the only piece of native bush remaining in its neighbourhood. We have been officially advised that this object has been attained. Manawatu Philosophical Society. 853 Besides the above, three questions of great importance have been before the Council, and been considered in detail by sub-committees and reported on to the different bodies more immediately concerned: — (1.) The alteration of the New Zealand mean time from eleven and a half to exactly twelve hours in advance of Greenwich, which would result in a daily saving of half an hour's sunlight, and bring the Dominion into line with the international agreement. This alteration was suggested by the Wellington Philosophical Society, and its consideration lias been postponed by the Government on account of the war. v (2.) A scheme for the better co-ordination of scientific work in the Dominion, brought forward by Mr. W. Ferguson, the Chairman of the Efficiency Board, and Dr. Thomson ; together with the comments thereon made by the different branches of the Institute in Auckland, Wellington, Canterbury, and Otago. A lengthy and detailed report on these proposals was made by the Council and forwarded to the Secretary of the New Zealand Institute for consideration at the annual meeting in January. (."!.) Proposals for the reorganization of the New Zealand Institute, initiated by Dr. Thomson, with a view to making it as a whole, apart from its branches, an active and efficient scientific body. These also were considered in detail with the comments of the various branches, and suggestions forwarded to the Secretary. In connection with bird-preservation the Council desires gratefully to acknowledge the aid given by Mr. W. H. Field, M.P., who took the keenest interest in the matter, and personally interviewed the Premier on the subject. During the year valuable additions to the Museum and the library have been received, including among other items a collection of fifty butterflies and moths from the Dominion Museum, contributed by Dr. Thomson ; a collection of minerals from the volcanic region of Rotorua, by Mr. D. Sinclair ; and valuable books of reference, by the Ven. Archdeacon Comins (late of Melanesia). For the first time this year the society has been called upon to contribute £6 15s 6d. towards the general expenses of the New Zealand Institute. As the chief item in these expenses is the publication of the Transactions, your Council has included in its sug- gestions for the reorganization of the New Zealand Institute the proposal that the Transactions should be issued gratuitously only to those members who make a written application for the same. At the annual meeting the following officers for 1918 were elected : President — A. J. Colquhoun, M.Sc. Vice-Presidents — C. T. Salmon, Assoc, in Eng. ; D. Sinclair, C.E. Officer in Charge of the Observatory — A. J. Colquhoun. Council — Miss Ironside, M.A. ; Messrs. H. Akers, J. L. Barni- coat, C. N. Clausen, M. A. Eliott, R. Gardner, A. Hannay, W. Park, J. Bainforth, J. E. Vernon, M.A. ; Dr. W. R. Stowe. Secretary and Trea- surer—^. Wilson, M.A. Auditor— W. E. Bendall, F.P.A.N.Z. WANGANUI PHILOSOPHICAL SOCIETY. Eight meetings were held during the session 1917, and various papers and exhibits submitted. The following were the principal papers con- tributed : " The Tropical Islands of the Eastern Pacific," by Dr. P. Marshall ; " Nebulae and Star Clusters," by Mr. J. T. Ward ; " History as a Factor in Education," by Mr. H. E. Sturge, M.A. ; " The Discovery of America," by Mr. Thomas Allison ; " New Zealand Provincialisms in the Use of English," Mr. J. A. Neame, M.A. ; " Records of Observations of Mr. A. W. Burrell, of Stratford, suggesting Comparatively Recent Volcanic Activity of Mount Egmont," contributed through Mr. J. T. Ward ; " Mendelism," by Dr. 12— Trans. 354- Wanganui Philosophical Society. F. W. Hilgeudorf ; "Tuna and Pa-tuna — Eels and Eel-weirs," by Mr. T. W. Downes. The last mentioned, and two technical geological papers by Dr. Marshall, were taken as read. An interesting event of the session was the presentation to Dr. P. Marshall, the President of the Society, of the Hutton Memorial Medal for the year 1917. The medal was awarded for researches in New Zealand geology. The presentation was made by His Excellency the Governor- General, at a public meeting on the 20th September, 1917, on the occasion of his visit to Wanganui to lay the foundation-stone of the Sargeant Art Gallery. Officers of the Society. — President— Dr. P. Marshall, F.R.G.S. Vice- Presidents — Mr. J. A. Neame, M.A., and Mr. J. T. Ward. Council (including Mr. H. Drew, ex officio as Hon. Curator of the Museum) — Messrs. T. Allison ; C. Palmer Brown, M.A., LL.B. ; R. Murdoch ; T. W. Downes ; H. E. Sturge, M.A. ; H. R. Hatherly, M.R.C.S. Hon. Treasurer— Mr. F. P. Talboys. Hon. Secretary — Mr. J. P. Williamson. Representative — Dr. Marshall. APPENDIX 357 NEW ZEALAND INSTITUTE ACT, 1908. For the New Zealand Institute Act, 1908, and Regulations thereunder see vol. 49, 1917, pp. 570-74. THE HUTTON MEMORIAL MEDAL AND RESEARCH FUND. Declaration of Trust. This deed, made the fifteenth day of February, one thousand nine hundred and nine (1909), between the New Zealand Institute of the one part, and the Public Trustee of the other part : Whereas the New Zealand Institute is possessed of a fund consisting now of the sum of five hundred and fifty- five pounds one shilling (£555 Is.), held for the purposes of the Hutton Memorial Medal and Research Fund on the terms of the rules and regu- lations made by the Governors of the said Institute, a copy whereof is hereto annexed : And whereas the said money has been transferred to the Public Trustee for the purposes of investment, and the Public Trustee now holds the same for such purposes, and it is expedient to declare the trusts upon which the same is held by the Public Trustee : Now this deed witnesseth that the Public Trustee shall hold the said moneys and all other moneys which shall be handed to him by the said Governors for the same purposes upon trust from time to time to invest the same upon such securities as are lawful for the Public Trustee to invest on, and to hold the principal and income thereof for the purposes set out in the said rules hereto attached. And it is hereby declared that it shall be lawful for the Public Trustee to pay all or any of the said moneys, both principal and interest, to the Treasurer of the said New Zealand Institute upon being directed so to do by a resolution of the Governors of the said Institute, and a letter signed by the Secretary of the said Institute enclosing a copy of such resolution certified by him and by the President as correct shall be sufficient evidence to the Public Trustee of the due passing of such resolution : And upon receipt of such letter and copy the receipt of the Treasurer for the time being of the said Institute shall be a sufficient discharge to the Public Trustee : And in no case shall the Public Trustee be concerned to inquire into the administration of the said moneys by the Governors of the said Institute. As witness the seals of the said parties hereto, the day and year hereinbefore written. Resolutions of Board of Governors. Resolved by the Board of Governors of the New Zealand Institute that — 1. The funds placed in the hands of the Board by the committee of subscribers to the Hutton Memorial Fund be called "The Hutton Memorial Research Fund," in memory of the late Captain Frederick 358 Appendix. Wollaston Hutton, F.K.S. Such fund shall consist of the moneys sub- scribed and granted for the purpose of the Hutton Memorial, and all other funds which may be given or granted for the same purpose. 2. The funds shall be vested in the Institute. The Board of Governors of the Institute shall have the control of the said moneys, and may invest the same upon any securities proper for trust-moneys. 3. A sum not exceeding £100 shall be expended in procuring a bronze medal to be known as " The Hutton Memorial Medal." 4. The fund, or such part thereof as shall not be used as aforesaid, shall be invested in such securities as aforesaid as may be approved of by the Board of Governors, and the interest arising from such investment shall be used for the furtherance of the objects of the fund. 5. The Hutton Memorial Medal shall be awarded from time to time by the Board of Governors, in accordance with these regulations, to persons who have made some noticeable contribution in connection with the zoology, botany, or geology of New Zealand. 6. The Board shall make regulations setting out the manner in which the funds shall be administered. Such regulations shall conform to the terms of the trust. 7. The Board of Governors may, in the manner prescribed in the regulations, make grants from time to time from the accrued interest to persons or committees who require assistance in prosecuting researches in the zoology, botany, or geology of New Zealand. 8. There shall be published annually in the "Transactions of the New Zealand Institute" the regulations adopted by the Board as afore- said, a list of the recipients of the Hutton Memorial Medal, a list of the persons to whom grants have been made during the previous year, and also, where possible, an abstract of researches made by them. Regulations under which the Hutton Memorial Medal shall be awarded and the research fund administered. 1. Unless in exceptional circumstances, the Hutton Memorial Medal shall be awarded not oftener than once in every three years ; and in no case shall any medal be awarded unless, in the opinion of the Board, some contribution really deserving of the honour has been made. 2. The medal shall not be awarded for any research published previous to the 31st December, 1906. 3. The research for which the medal is awarded must have a distinct bearing on New Zealand zoology, botany, or geology. 4. The medal shall be awarded only to those who have received the greater part of their education in New Zealand or who have resided in New Zealand for not less than ten years. 5. Whenever possible, the medal shall be presented in some public manner. 6. The Board of Governors may, at an annual meeting, make grants from the accrued interest of the fund to auy person, society, or commit- tee for the encouragement of research in New Zealand zoology, botany, or geology. 7. Applications for such grants shall be made to the Board before the 30th September. 8. In making such grants the Board of Governors shall give preference to such persons as are defined in regulation 4. Hutton Memorial Fund. 359 9. The recipients of such grants shall report to the Board before the 31st December in the year following, showing in a general way how the grant has been expended and what progress has been made with the research. 10. The results of researches aided by grants from fcbie mud shall, where possible, be published in New Zealand. 11. The Board of Governors may from time to time amend or alter the regulations, such amendments or alterations being in all cases in con- formity with resolutions 1 to 4. Award of the Hutton Memorial Medal. 1911. Professor W. B. Benham, D.Sc.. F.R.S., University of Otago- For researches in New Zealand zoology. 1914. Dr. L. Cockayne, F.L.S., F.R.S. — For researches on the ecology of New Zealand plants. 1917. Professor P. Marshall, M.A., D.Sc. — For researches in New Zealand geology. HECTOR MEMORIAL RESEARCH FUND. Declaration of Trust. This deed, made the thirty-first day of July, one thousand nine hundred and fourteen, between the New Zealand Institute, a body corporate duly incorporated by the New Zealand Institute Act, 1908, of the one part, and the Public Trustee of the other part : Whereas by a declara- tion of trust dated the twenty-seventh day of January, one thousand nine hundred and twelve, after reciting that the New Zealand Institute was possessed of a fund consisting of the sum of £1,045 10s. 2d., held for the purposes of the Hector Memorial Research Fund on the terms of the rules and regulations therein mentioned, which said moneys had been handed to the Public Trustee for investment, it was declared {inter aha) that the Public Trustee should hold the said moneys and all other moneys which should be handed to him by the said Governors of the Institute for the same purpose upon trust from time to time, to invest the same in the common fund of the Public Trust Office, and to hold the principal and income thereof for the purposes set out in the said rules and regula- tions in the said deed set forth : And whereas the said rules and regu- lations have been amended by the Governors of the New Zealand Institute, and as amended are hereinafter set forth : And whereas it is expedient to declare that the said moneys are held by the Public Trustee upon the trusts declared by the said deed of trust and for the purposes set forth in the said rules and regulations as amended as aforesaid : Now this deed witnesseth and it is hereby declared that the Public Trustee shall hold the said moneys and all other moneys which shall be 360 Appendix. handed to him by the said Governors for the same purpose upon trust from time to time to invest the same in the common fund of the Public Trust Office, and to hold the principal and income thereof for the pur- poses set out in the said rules and regulations hereinafter set forth : And it is hereby declared that it shall be lawful for the Public Trustee to pay, and he shall pay, all or any of the said moneys, both principal and interest, to the Treasurer of the said New Zealand Insti- tute upon being directed to do so by a resolution of the Governors of the said Institute, and a letter signed by the Secretary of the said Insti- tute enclosing a copy of such resolution certified by him and by the President as correct shall be sufficient evidence to the Public Trustee of the due passing of such resolution : And upon receipt of such letter and copy the receipt of the Treasurer for the time being of the said Institute shall be a sufficient discharge to the Public Trustee : And in no case shall the Public Trustee be concerned to inquire into the adminis- tration of the said moneys by the Governors of the said Institute. As witness the seals of the said parties hereto, the day and year first hereinbefore written. Rules and Regulations made by the Governors of the New Zealand Institute in relation to the Hector Memorial Research Fund. 1. The funds placed in the hands of the Board by the Wellington Hector Memorial Committee be called " The Hector Memorial Research Fund," in memory of the late Sir James Hector, K.C.M.G., F.R.S. Ihe object of such fund shall be the encouragement of scientific research in New Zealand, and such fund shall consist of the moneys subscribed and granted for the purpose of the memorial and all other funds which may be given or granted for the same purpose. 2. The funds shall be vested in the Institute. The Board of Go- vernors of the Institute shall have the control of the said moneys, and may invest the same upon any securities proper for trust-moneys. 3. A sum not exceeding one hundred pounds (£100) shall be expended in procuring a bronze medal, to be known as the Hector Memorial Medal. 4. The fund, or such part thereof as shall not be used as aforesaid, shall be invested in such securities as may be approved by the Board of Governors, and the interest arising from such investment shall be used for the furtherance of the objects of the fund by providing thereout a prize for the encouragement of such scientific research in New Zealand of such amount as the Board of Governors shall from time to time determine. 5. The Hector Memorial Medal and Prize shall be awarded annually by the Board of Governors. 6. The prize and medal shall be awarded by rotation for the follow- ing subjects, namely — (1) Botany, (2) chemistry, (3) ethnology, (4) geo- logy, (5) physics (including mathematics and astronomy), (6) zoology (inchiding animal physiology). In each year the medal and prize shall be awarded to that investi- gator who, working within the Dominion of New Zealand, shall in the opinion of the Board of Governors have done most towards the advance- ment of that branch of science to which the medal and prize are in such year allotted. 7. Whenever possible the medal shall be presented in some public manner. Hector Memorial Research Fund. 361 Award of the Hector Memorial Research Fund. 1912. L. Cockayne, Ph.D., F.L.S., F.R.S. — For researches in New- Zealand botany. 1913. T. H. Easterfield, M.A., Ph.D. — For researches in chemistry. 1914. Elsdon Best- — For researches in New Zealand ethnology. 1915. P. Marshall, M.A., D.Sc, F.G.S. — For researches in New Zealand geology. 1916. Sir Ernest Rutherford, F.R.S. — For researches in physics. 1917. Charles Chilton, M.A., D.Sc, F.L.S., C.M.Z.S. - - For researches in zoology. 1918. T. F. Cheeseman, F.L.S., F.Z.S.— For researches in New Zealand systematic botany. REGULATIONS FOR ADMINISTERING THE GOVERNMENT RESEARCH GRANT. All grants shall be subject to the following conditions, and each grantee shall be duly informed of these conditions : — 1. All instruments, specimens, objects, or materials of permanent value, whether purchased or obtained out of or by means of the grant, or supplied from among those at the disposal of the Institute, are to be regarded, unless the Research Grants Committee decide otherwise, as the property of the Institute, and are to be returned by the grantee, for disposal according to the orders of the committee, at the conclusion of his research, or at such other time as the committee may determine. 2. Every one receiving a grant shall furnish to the Research Grants Committee, on or before the 1st January following upon the allotment of the grant, a report (or, if the object of the grant be not attained, an in- terim report, to be renewed at the same date in each subsequent year until a final report can be furnished or the committee dispense with further reports) containing (a) a brief statement showing the results arrived at or the stage which the inquiry has reached ; (6) a general statement of the expenditure incurred, accompanied, as far as is possible, with vouchers : (c) a list of the instruments, specimens, objects, or materials purchased or obtained out of the grant, or supplied by the committee, which are at present in his possession ; and (d) references to any transactions, journals, or other publications in which results of the research have been printed. In the event of the grantee failing to send in within three months of the said 1st January a report satisfactory to the committee he may be required, on resolution of the Board of Governors, to return the whole of the sum allotted to him. 3. Where a grant is made to two or more persons acting as a committee for the purpose of carrying out some research, one member of the said committee shall assume the responsibility of furnishing the report and receiving and disbursing the money. 4. Papers in which results are published that have been obtained through and furnished by the Government grant should contain an acknow- ledgment of that fact. 13— Trans. 362 Appendix. 5. Every grantee shall, before any of the grant is paid to him, be required to sign an engagement that he is prepared to carry out the general conditions applicable to all grants, as well as any conditions which may be attached to his particular grant. 6. In cases where specimens or preparations of permanent value are obtained through a grant the committee shall, as far as possible, direct that such specimens shall be deposited in a museum or University college within the province where the specimens or material were obtained, or in which the grantee has worked. The acknowledgment of the receipt of the speci- mens by such institution shall fully satisfy the claims of the Institute. 7. In cases where, after completion of a research, the committee directs that any instrument or apparatus obtained by means of the grant shall be deposited in an institution of higher learning, such deposit shall be subject to an annual report from the institution in question as to the condition of the instrument or apparatus, and as to the use that has been made of it. Research Grants from Vote (£500) to 31st March, 1918. Through the Philosophical Institute of Canterbury : — Professor W. P. Evans, £200 for the investigation of New Zealand brown coals; granted 11th March, 1918. Professor Charles Chilton. £50 for the investigation of New Zealand flax (phormium) ; granted 11th March, 1918. Through the Otago Institute : — Professor John Malcolm. £30 for the investigation of New Zealand plant pharmacology; granted 11th March, 1918. Through the Wellington Philosophical Society:— Professor T. H. Easterfield, £50 for investigation of the wax content of New Zealand brown coals ; granted 11th March, 1918. THE CARTER BEQUEST. For extracts from the will of Charles Rooking Carter see vol. 48, 1916, pp. 565-66. 363 NEW ZEALAND INSTITUTE ESTABLISHED UNDER AN ACT OF THE GENERAL ASSEMBLY OF NEW ZEALAND INTITULED THE NEW ZEALAND INSTITUTE ACT, 1867; RECONSTITUTED BY AN ACT OF THE GENERAL ASSEMBLY OF NEW ZEALAND UNDER THE NEW ZEALAND INSTITUTE ACT, 1908, AND CONTINUED BY THE NEW ZEALAND INSTITUTE ACT, 1908. BOARD OF GOVERNORS. EX OFFICIO. His Excellency the Governor-General. •j The Hon. the Minister of Internal Affairs. NOMINATED BY THE GOVERNMENT. Mr. Charles A. Ewen (reappointed December, 1916) ; Dr. J. Allan Thom- son, P.G.S. (reappointed December, 1917) ; Mr. B. C. Aston, F.I.C., F.C.S. (reappointed December, 1917) ; Dr. Charles Chilton, F.L.S., C.M.Z.S. (reappointed December, 1916). ELECTED BY AFFILIATED SOCIETIES (DECEMBER, 1917). (Professor H. B. Kirk, M.A. ■(Mr. George Hogben, M.A., ( C.M.G. (Professor H. W. Segar, M.A. -j Professor A. P. W. Thomas, I M.A. (Dr. F. W. Hilgendorf, M.A. I Mr. L. Birks, B.Sc. (Mr. G. M. Thomson, F.C.S., F.L.S. (Mr. E. J. Parr, M.A. , B.Sc. Mr. H. Hill, B.A., F.G.S. Dr. L. Cockavne, F.L. S. , F.B.S. Mr. M. A. Eliott. Dr. P. Marshall, F.G.S. Wellington Philosophical Society Auckland Institute Philosophical Institute of Canterbury Otago Institute Hawke's Bay Philosophical Institute .. Nelson Institute Manawatu Philosophical Society Wanganui Philosophical Society OFFICERS FOR THE YEAR 1918. President : Dr. L. Cockayne, F.E.S. Hon. Treasurer: Mr. C. A. Ewen. Hon. Editors : Dr. L. Cockayne, F.R.S. ; Dr. C. A. Cotton, F.G.S. Hon. Librarian : Dr. J. Allan Thomson, F.G.S. Hon. Secretary: Mr. B. C. Aston, F.I.C., F.C.S. (Box 40, Post-office, Wellington). AFFILIATED SOCIETIES. Name of Society. Secretary's Name and Address. Date of Affiliation. Wellington Philosophical J. Allan Thomson, Dominion 10th June, 1868. Society Museum, Wellington Auckland Institute T. F. Cheeseman, Museum, Auck- land L. P. Symes, 22 Mays Road, 10th June, 1868. Philosophical Institute of 22nd October, 1868. Canterbury Christchurch Otago Institute E. J. Parr, Boys' High School, Dunedin 18th October, 1869. Hawke's Bay Philosophical C. F. H. Pollook, P.O. Box 166, 31st March, 1875. Institute Napier Nelson Institute E. L. Morley, Waimea Streei,, Nelson 20th December, 1883. Manawatu Philosophical K. Wilson, 92 Rangitikei Street, 6th January, 1905. Society Palmerston North Wanganui Philosophical J. P. Williamson, Box 171, Wa- 2nd December, 1911. Society nganui 13" 364 Appendix. FORMER HONORARY MEMBERS. 1870. Agassiz, Professor Louis. Drury, Captain Byron, R.N. Finsoh, Professor Otto, Ph.D. Flower, Professor W. H., F.R.S. Hochstetter. Dr. Ferdinand von. Darwin, Charles. M.A., F.R.S. Gray, J. E., Ph.D., F.R.S. Hooker, Sir J. D., G. C.S.I. , C.B., M.D , F.R.S., O.M. Mueller, Ferdinand von, M.D., F.R.S. C.M.G. Owen, Professor Richard, F.R.S. Richards, Rear-Admiral G. H. 1871. Lindsay, W. Lauder, M.D., F.R.S.E. Grey, Sir George, K.C.B. Huxley, Thomas H., LL.D., F.R.S. 1872. I Stokes, Vice- Admiral J. L. 1873. Bowen, Sir George Ferguson, G. C.M.G. Giinther, A.. M.D., M.A., Ph.D., F.R.S. Lyell, Sir Charles, Bart., D.C.L., F.R.S. Pickard-Cambridge, Rev. O., M.A., F.R.S., C.M.Z.S. McLachlan, Robert, F.L.S. Newton, Alfred, F.R.S. 1874. Thomson, Professor Wyville, F.R.S. Filhol, Dr. H. Rolleston, Professor G., M.D., F.R.S. 1875. Sclater, P. L., M.A., Ph.D., F.R.S. Berggren, Dr. S. Clarke. Rev. W. B., M.A., F.R.S. Baird, Professor Spencer F. 1876. Etheridge, Professor R., F.R.S. 1877. I Weld, Frederick A., C.M.G. Garrod, Professor A. H., F.R.S. Miiller, Professor Max, F.R.S. 1878. Tenison- Woods, Rev. J. E., F.L.S. 1880. The Most Noble the Marquis of Normanby, G.C.M.G. Carpenter, Dr. W. B., C.B., F.R.S. Ellery, Robert L. J., F.R.S. 1883. Thomson, Sir William, F.R.S. Gray, Professor Asa. Sharp, Richard Bowdler, M.A., F.R.S. 1885. Wallace, A. R., F.R.S., O.M. 1888. Beneden, Professor J. P. van. Ettingshausen, Baron von. McCoy, Professor F., D.Sc, C.M.G., F.R.S. Former Honorary Members. 1890. Riley, Professor C. V. 1891. Davis, J. W., F.G.S., F.L.S. 1895. Mitten, William, F.R.S. 365 Langley, S. P. Agardh, Dr. J. G. Avebury, Lord, P.C., F.R.S. Eve, H. W., M.A. 1896. | Lydekker, Richard, F.R.S. 1900. Massee, George, F.L.S., F.R.M.S. 1901. I Howes, G. B., LL.D., F.R.S. 1906. Milne, J., F.R.S. 1909. Darwin, Sir George, F.R.S. FORMER MANAGER AND EDITOR. [Under the New Zealand Institute Act, 1867.] 1867-1903. Hector, Sir James, M.D., K.C.M.G., F.R.S. PAST PRESIDENTS. 1903-4. Hutton, Captain Frederick Wollaston, F.R.S. 1905-6. Hector, Sir James, M.D., K.C.M.G., F.R.S. 1907-8. Thomson, George Malcolm, F.L.S., F.C.S. 1909-10. Hamilton, A. 1911-12. Cheeseman, T. F., F.L.S. , F.Z.S. 1913-14. Chilton, C, M.A., D.Sc, LL.D., F.L.S., C.M./.S. 1915. Petrie, D., M.A., Pb.D. 1916-17. Benham, W. B., M.A., D.Sc.,, F.Z.S., F.R.S. 366 Appendix. HONOBABY MEMBBES. 1877. Sharp, Dr. D., University Museum, Cambridge. 1890. Liversidge, Professor A., M.A., P.R.S., ! Nordstedt, Professor Otto, Ph.D., Uui- Pieldhead, Coombe Warren, Kingston versity of Lund, Sweden. Hill, England. ! 1891. Goodale, Professor G. L., M.D., LL.D., Harvard University, Massachusetts, U.S.A. 1894. Codrington, Rev. P. H., D.D., Wadhurst Thiselton - Dyer. Sir W. T.. K.C.M.G., Rectorv, Sussex, England. CLE., LL.D., M.A., P.R.S., Witcombe, Gloucester, England. 1901. Goebel, Professor Dr. Carl von, University of Munich. 1902. Sars, Professor G. 0., University of Christiania, Norway. 1903. Klotz, Professor Otto J., 437 Albert Street, Ottawa, Canada. 1904. Rutherford, Professor Sir E., D.Sc, | David, Professor T. Edgeworth, P.R.S., P.R.S., Nobel Laureate, University of I C.M.G., Sydney University, N.S.W. Manchester. 1906. Beddard, P. E., D.Sc, F.R.S., Zoological Society, London. Brady, G. S., D.Sc, F.R.S., University of Durham, England. 1907, Dendy, Dr. A., P.R.S., King's College, University of London, England. Diels, Professor L., Ph.D., University of Marburg. Meyrick, E., B.A., P.R.S., Marlborough College, England. Stebbing, Rev. T. R. R., P.R.S., Tun- bridge Wells, England. 1910. Bruce, Dr. W. S., Edinburgh. 1913. Davis, Professor W. Morris, Harvard | Hemsley, Dr. W. Botting, P.R.S., Straw- University. ' berry Hill, London, England. 1914. Arber, Dr. E. Newell, Cambridge, England. Balfour, Professor I. Bayley, P.R.S., Royal Botanic Gardens, Edinburgh. Haswell, Professor W. A., P.R.S, Uni- versity, Sydney. 1915. Bateson, Professor W., P.R.S., Merton, Surrey, England. 1916. Massaut, Professor Jean, University of Brussels, Belgium. Roll of Members. 367 ORDIN AR Y MEMBK H S . WELLINGTON PHILOSOPHICAL SOCIETY. [* Life members t On active service.] Ackland. E. W., P.O. Box 928, Wellington. Adams, C. E., D.Sc., A. LA. (London), F.R.A.S., Hector Observatory, Wellington. Adams. ('. W., Bellevue Road, Lower Hutt.* Adamson, Professor J., M.A., LL.B., Victoria University College. Wellington. Adkin, G. L., Queen Street. Levin. Andersen, Johannes C, General Assembly library, Wellington. Anderson, W. J., M.A., LL.D.. Education Department . Wellington. Andrew, K. L., Dominion Laboratory. Wel- lington. Aston. B.C., F.I.C., F.C.S., P.O. Box 40, Wellington. Atkins, A.. F.R.I.B.A., A.M.Inst.C.E.. 9 Grey Street. Wellington. Atkinson. E. H., Agricultural Department, Wellington. t Bagley, G., care of Young's Chemical Coin pany, 14 Egrnont Street, Wellington. Baillie. H, Public Library, Wellington. Bakewell, F. H., M.A., Education Board. Mercer Street, Wellington. Baldwin. E. S.. 215 Lambton Quay, Wel- lington. Beetham. W. H., Masterton. Begg, Dr. C. M., 1 04 Willis Street, Wellington.t Bell. E. D.. Panama Street, Wellington. Bell. Hon. Sir Francis H. D., K.C., M.L.C.. Panama Street. Wellington. Berry, C. G. G., 35 Bolton Street, Wellington. Blair, David K.. MJ.Mech.E., 9 Grey Street. Wellington. Brandon, A. de B., B.A., Featherston Street, Wellington. Bretherton, A. C, Public Trust Office, Wel- lington. Bridges, G. G. 2 Wesley Road, Wellington. Broadgate. F. L. K., M.Sc., Dominion Museum. Wellington.t Brodrick, T. N., Under-Secretary, Lands and Survey Department, Wellington. Brown, J., Experimental Farm, Weraroa. Browne, M. H., Education Department, Wel- lington. Burbidge. P. W.. M.Sc, Victoria University College, Wellington.f Burnett, J., M.Inst. C.E., care of M. Burnett, of Richardson, McCabe. and Co., 11 Grey Street, Wellington. Burton, Richard F., Longner Hall. Salop, Shrewsbury, England.* Cameron, Dr. R. A., 148 Willis Street, Wel- lington. Campbell, J., F.R.I.B.A., Government Archi- tect, Public Works Department, Welling- ton. Carter, W. H., care of Dr. Henry, The Terrace, Wellington.t Chamberlin, T. Chamberlin, Crescent Road, Khandallah. Chapman, Martin, K.C., Brandon Street, Wellington. Chudleigh, E. R., Orongomairoa. Waihou. Clark, Professor H., Victoria University Col- lege, Wellington. Clarke, J. T., care of Messrs. Searle, Joy. and Co., 61 Victoria Street, Wellington. Cockayne. L., Ph.D., F.L.S., F.R.S., Ngaio, Wellington. Connie, L. J., M.A., Wapiti Avenue, Epsom, Auckland. Cotton, C. A., D.Sc, F.G.S., Victoria Univer- sity College, Wellington. Crawford, A. D., Box 120, G.P.O., Wellington. Cull. J. E. L., B.Sc. in Eng. (Mech.), Public Works Department. Wellington. Curtis, H. F.. 19 .May Street, Wellington. Darling, J., Kelburn. Davies, V. C, Devon Street, New Plymouth.t Donovan. W., M.Sc, Dominion Laboratory, Wellington. Dore, A. B., Bacteriological Laboratory, Wellington. Dougall, Archibald, 9 Claremont Grove. Wel- lington . Dymock, E. R., F.I.A.N.Z., A.I.A.V., Wood- ward Street, Wellington. Earnshaw, W., 4 Watson Street, Wellington.t Easterfield, Professor T. H., M.A., Ph.D., Victoria University College, Wellington. Ewen, Charles A., Heretaunga, Upper Hutt. Ferguson, William. M.A., M. Inst.C. E., M.I.Mech.E.. 131 Coromandel Street, Wel- lington. Findlay. Sir John G., K.C., LL.D., 197 Lambton Quay. Wellington. FitzGerald, Gerald, A.M.Inst.C.E., P.O. Box 401 , Wellington. Fletcher, RevT H. J., The Manse, Taupo. Fortune, Alfred, Huia Road, Hataitai. Fox, Thomas 0.. Borough Engineer, Miramar, Wellington. Freeman, C. J., 95 Webb Street, Wellington.* Freyberg, C, Macdonald Crescent, Welling- ton.t Fulton, J.. 14 North Terrace, Kelburn. t Furkert, F. W.. A.M.Inst.C.E., Public Works Department, Wellington. 368 Appendix. Garrow, Professor J. M. E., B.A., LL.B., Victoria University College, Wellington.* Gavin, W. H., Public Works Department, Wellington. Gibbs, Dr. H. E., 240 Willis Street, Welling- ton. Gilford, A. C, M.A., F.R.A.S., G Shannon Street, Wellington.* Girdlestone, H. E., F.R.G.S., Lands and Survey Department. Wellington. Goudie, H. A., Whakarewarewa. Gray, W., Mauriceville. Hamilton. H., A.O.S.M., 58 Bowen Street, Wellington.t Hanify, H. P., 18 Panama Street, Wellington. Hansford, George D., Parliamentary Build- ings, Wellington. Hastie, Miss J. A., care of Street and Co., 30 Cornhill, London E.C. * Hector, C. Monro, M.D., B.Sc, F.R.A.S., Lower Hutt. Helyer, Miss E., 13 Tonks Grove, Wellington. Henderson, J., M.A., D.Sc, B.Sc. in Eng. (Metall.). Geological Survey Department, Wellington. Hislop, J., Internal Affairs Department, Wel- lington. Hodson, W. H., 40 Pirie Street, Wellington. Hogben, G., C.M.G., M.A., F.G.S., 32 Crescent Road, Khandallah. Holmes, R. L., F.R.Met.Soe.. " Kia Ora," Fern Street, Randwick, Sydney.* Holmes, R. W., M.Inst.GE., Engineer-in- Chief, Public Works Department, Welling- ton. Hooper, Captain G. S., Grant Road, North Wellington. Hudson, G. V., F.E.S., Inspector's Office, G.P.O., Wellington. Jack, J. W., 170 Featherston Street, Wel- lington. James, L. G., P.O. Box 94. (Hunter Street), Wellington. Jenkinson, S. H., Railway Department, Wel- lington. Johnston, Hon. G. Randall, care of Martin Chapman, K.C., Wellington.* Jones, E. G, B.A., 33 Ellice Avenue, Wel- lington, f Joseph, Joseph, P.O. Box 443, Wellington. Kempthorne, Mrs. H. E., Bellevue Road, Lower Hutt. Kennedy, Rev. Dr. D., F.R.A.S., St. Patrick's College, Wellington. King, G. W., B,E., care of A. H. King, P.O. Box 116, Christchurch.t Kirk, Professor H. B., M.A., Victoria Univer- sity College, Wellington. La Trobe, W. S., M.A., Technical College, Wellington. Lawton, H. W., Education Board, Welling- ton. Levi, P., M.A., care of Wilford and Levi, 15 Stout Street. Wellington. Lomas, E. K., M.A., M.Sc, Training College, Wellington. Li.niax, Major H. A.. Araruhe, Aram oho, Wanganui. Luke, John P., C.M.G., M.P., Hiropi Street, Wellington. McCabe. Ultan F., cue of Richardson and McCahe, 11 Grey Street. Wellington. McDonald, J., Dominion Museum, Wellington. McKenzie, Donald, care of Mrs. Elizabeth McKenzie, Mart on. f MacJaurin, J. S., D.Sc, F.C.S., Dominion Laboratory, Wellington. MacLean, F. W., M.Inst. C.E., Chief Engineer, Head Office, Railway Department, Wel- lington. Marchbanks, J., M.Inst.C.E., Harbour Board, Wellington. Marsden. Professor E., D.Sc, Victoria Uni- versity College, Wellington.t Mason, J. Malcolm, M.D., F.C.S., D.P.H., Lower Hutt. Maxwell, J. P., M.Inst.C.E., 145 Dixon Street, Wellington. Mestayer, R. L., M.Inst.C.E., 139 Sydney Street, Wellington. Millar, H. M., Public Works Department, Wellington.! Mills, Leonard, New Parliamentary Buildings, Wellington. Moore, G, Eparaima. via Masterton. Moore, W. Lancelot, care of H. D. Cook, Bank Chambers, Lambton Quay, Welling- ton.t Moorhouse, W. H. Sefton, 134 Dixon Street, Wellington. Morgan, P. G, M.A., F.G.S., Director of Geo- logical Survey, Routh's Buildings, Welling- ton. Morice, J. M., B.Sc, Town Hall, Wellington. Morison, C. B., Stout Street, Wellington. Morrison, J. C, P.O. Box 8, Eltham. Morton, W. H., M.Inst.C.E., City Engineer, Wellington. Myers, Miss P., B.A., 26 Fitzherbert Terrace, Wellington. Newman, A. K., M.B., M.R.C.P., M.P., 56 Hobson Street, Wellington. Nicol, John, 57 Cuba Street, Wellington. Norris, E. T., M.A., Registrar, University of Xew Zealand, Wellington. Ongley, M., M.A., Geological Survey Depart- ment, Wellington.t Orchiston. J., M.I.E.E., 16 Rimu Road, Kel- burn. Orr, Robert, Heke Street, Lower Hutt, Wel- lington. Parry, Evan, B.Sc, M.I.E.E., A.M.Inst.C.E., Electrical Engineer, Public Works Depart- ment, Wellington. Paterson, A. J., City Engineer's Office, Town Hall, Wellington. Patterson, Hugh, Assistant Engineer, Public Works Office, Ngatapa. Pearce, Arthur E., care of Levin and Co. (Limited), Wellington- Phillips, Coleman. Carterton.* Roll of Members. 369 Phillipps, W. J., Dominion Museum, Welling- ton. Phipson, P. B., F.C.S., care of J. Staples and Co. (Limited), Wellington. Pierard, A. C, Bacteriological Laboratory, Wellington. Pigott, Miss Ellen, M.A., Victoria University College. Wellington. Pomare, Hon. Dr. M., M.P., Wellington. Porteous, J. S.. 9 Brandon Street, Wellington. Porter. Colonel T. W., 12 Austin Street. Wel- lington. Powles. C. P.. 219 Lambton Quay, Wellington. Reakes, C. J., D.V.Sc., M.R.C.V.S., Agricul- tural Department, Wellington. Reid, W. S., 189 The Terrace, Wellington. Richardson, C. E., P.O. Box 863 (11 Grey Street), Wellington. Roy, R. B., Taita. Wellington.* Salmond, J. W., K.C., M.A., L.L.B., Crown Law Office, Wellington. Short, W. S., Under-Secretary, Public Works Department, Wellington. Shrimpton, E. A.. Telegraph Department, Wellington. Sladden, H., Lower Hutt, Wellington. Smith, M. Crompton, Lands and Survey De- partment, Wellington. Sommerville. Professor D. M. Y., M.A., D.Sc, F.R.S.E., Victoria University College, Wel- lington. Spencer, W. E., M.A , M.Sc, Education De- partment. Wellington. Stout, T. Duncan M.. M.B., M.S., F.R.C.S., 16-1 Willis Street. Wellington^ Sunley, R. M., View Road, Karori. Tennant, J. S., M.A., B.Sc, Training College, Wellington. Thomas, J., South Wellington School. Thompson, R. D., M.A., Victoria University College, Wellington. Thomson, J. Allan, M.A.. D.Sc, F.G.S., Dominion Museum, Wellington. Thomson, John, B.E., M.Inst.C.E., 17 Dork- ing Road, Brooklyn, Wellington. Thomson, W. M., M.A., M.B.. Ch.B., Hawera. Tily, H. S., B.Sc, H.M. Customs. Wellington.! Tolley, H. R„ 34 Wright Street, Wellington. Tombs, H. H., Burnell Avenue. Wellington. Treadwell, C. H.. 4 Panama Street. Wellington. Turnbull, Alex. H., Bowen Street. Wellington. Turner, E. Phillips, F.R.G.S., Lands and Sur- vey Department. Wellington. Uttley, <;.. M.A.. M.Sc, F.G.S., Scots College, Wellington. Vickerman, H., M.Sc, A.M.Inst.C.E., Public Works Department, Wellington. t W'ardrop, J. H. W.. Lands Department, Wel- lington. Welch, J. S., 52 Wright Street. Wellington. Westland, C. J., F.R.A.S., Hector Observa- tory, Wellington. f Widdop, F. G, District Railway Engineer, Thorndon Office, Wellington. Wilmot, E. H., Surveyor-General, Wellington. Wilson, Sir James G., Bull's. Wynne, H. J., Railway Department, Welling- ton. AUCKLAND INSTITUTE. [* Honorary and life members.] Abbott, R. H., Elliott Street, Auckland. Abel, R. S., care of Abel, Dykes, and Co., Shortland Street, Auckland. Adams, L., 23 Brown Street, Ponsonby. Adlington, Miss, Aratonga Avenue, Epsom. Aickin, G., Queen Street, Auckland. Alexander. J., Shortland Street, Auckland. Alexander, L. W., " Beauvoir," Hurstmere Road, Takapuna. Alison, A., Devonport Ferry Company, Auck- land. Alison. E. W., Devonport Ferry Company, Auckland. Alison. E. W., jun., Bank of New Zealand Chambers, Swanson Street, Auckland. Alison. Ernest, Bank of New Zealand Cham- bers, Swanson Street. Auckland. Allen, John, Cheltenham Avenue, Devonport. Allum, John. National Electricaland Engineer- ing Company, Wellesley Street, Auckland. Am bury, S. J.. <'i-eenwood's Corner, One- hunga. Anderson, E., Fort Street, Auckland. Ardern, P. S., Remuera. Ai-ey, W. E., Victoria Arcade, Auckland. Armitage, F. L.. New Zealand Expeditionary Forces. Arnold, C, Swanson Street, Auckland. Arnoldson, L., Quay Street, Auckland. Arthur, T. B., Elliott Street, Auckland. Atkinson, H., Grafton Road, Auckland. Bagnall, H. N., Mason's Avenue, Ponsonby. Baker, G. H., Commerce Street, Auckland. Ball, W. T., Sylvan Avenue, Mount Eden. Bamford, H. D., LL.D., Bank of New Zealand Buildings, Auckland. Bankart, A. S., Strand Arcade, Queen Street, Auckland. Bankart, F. J., Shortland Street. Auckland. Barr, J., Public Library, Wellesley Street, Auckland. Barr, J. M , Auckland Savings-bank, Auckland. Barry, S., Queen Street, Auckland. Bart left, W. H.. Queen Street, Auckland. Bartrum, J. A., M.Sc, University College, Auckland. Bates, T. L., '■ Brookfield," Alfred Street, Waratah, Newcastle, New South Wales.* Batger, J., Mount Eden Road, Auckland. Beattie, Dr. R. M., Mental Hospital, Avondale. :i7<> Apjtendix. Bell, T., Union Soap and Candle Company, Albert Street, Auckland. Benjamin, Lionel. P. Hayman and Co., Customs Street. Auckland. 'Binney, E. H., G. W. Binney and Sons, Fort Street. Auckland. Biss. N. L. H.. Shortland Street, Auckland. Blair, J. M., Market Road, Epsom. Blomfield, E. C, Parr and Blomfield, Short- land Street, Auckland. Blomfield, W., Observer Office, Wyndham Street. Auckland. Bloomfield, G. R., "The Pines," Epsom.* Bloomfield, H. R., St. Stephen's Avenue, Parnell.* Bloomfield, J. L. N. R., St. Stephen's Avenue, Parnell. Bowyer, S. B., New Zealand Expeditionary Forces, France. Bradley, Samuel, Onehunga. Bradney, H., Queen Street Wharf, Auckland. Brett, H., Star Office, Shortland Street, Auckland. Briffault, R., M.D., New Zealand Expedition- ary Forces. Brooke-Smith, E.. Manukau Road, Parnell. Broun, Major T., F.E.S., Chevalier of the Legion of Honour, Mount Albert. Brown, E. A., Cleave's Buildings. High Street, Auckland. Brown, John, Beresford Street, Bayswater. Bruce, W. W., Williamson Chambers, Short - land Street. Buchanan, A., Vulcan Lane, Auckland.* Buckleton, H., Bank of New Zealand, Auck- land. Buddie, C, Wyndham Street, Auckland. Buddie, T., Wyndham Street, Auckland. Burnett, H. B., Harbour Board Offices, Auckland. Burns, R., Customs Street, Auckland. Burt, A., A. T. Burt and Co., Customs Street, Auckland. Bush, W. E., City Engineer. Auckland. Butler, J., Kauri Timber Company, Customs Street, Auckland. Butler, Miss, Girls' Grammar School, Auckland. Buttle, G. A., Hobson Buildings, Shortland Street, Auckland. Buttle, J., New Zealand Insurance Company, Queen Street, Auckland. Cadman, F. P., Hoiland, Gillett, and Co., Customs Street, Auckland. Caldwell, D. R., Macky, Logan, and Co., Elliott Street, Auckland. Campbell, J. P., Russell, Campbell, and McVeagh, High Street, Auckland. Carlaw, J., 226 Symonds Street, Auckland. ( 'arpenter, J. M., Newmarket. Carr, E. J., Williamson Avenue, Grey Lynn. Carse, H., Kaiaka, Mangonui. Carter. M., Smeet on's Buildings, Queen Street, Auckland. Casey, Maurice. Hamilton Road, Ponsonby. Casey, Victor P., New Street, Ponsonby. Casey, W., Hamilton Road, Ponsonby. Caughey, A. ('.. Smith and Caughey (Limited), Queen Street. Auckland. Caughey, J. Marsden, Smith and Caughey (Limited). Queen. Street, Auckland. Chambers. S. C. 106 Victoria Arcade, Queen Street, Auckland. Chatfield, Dr. H. A., Victoria Street East, Auckland. Cheat, P. E., Upper Queen Street. Auckland. Cheeseman, T. F., F.L.S., F.Z.S., Museum, Auckland. Choyce. H. G, Remuera Road, Auckland. Clark, A., Wellesley Street, Auckland. Clark. H. ('., Wellesley Street, Auckland. Clark, M., Wellesley Street, Auckland. Clark. R. (i., Robertson Bros., Quay Street, Auckland. Clay, T. B., S. Vaile and Sons. Queen Street, Auckland. Clayton. C. Z., Ellerslie. Clayton, D. L.. Kauri Timber Company, Customs Street. Auckland. Coates, T., Orakei. Coe, James, Mount Eden Road, Auckland Colbeck, W. B., Fort Street, Auckland. Cole, Rev. R. H., Walford, Gladstone Road, Parnell. Cole, W.. Mount Eden Road, Auckland. Coleman, J. W., Lower Queen Street, Auck- land. Combes, F. H.,' Victoria Avenue. Remuera. Cooper, G, Bourne Street, Mount Eden. Cooper, Mr. Justice. Supreme Court, Auckland. Copeland, M., 97 College Hill, Auckland. Cory-Wright, S., B.Sc. New Zealand Expedi- tionary Forces, France. Court, G.. Karangahape Road, Auckland. Court. J., Ponsonby, Auckland. Court, J. W., J. Court (Limited), Queen Street, Auckland. Cousins, H. G, Normal School. Wellesley Street, Auckland. Craig, E. A., J. J. Craig (Limited), Queen Street, Auckland. Crompton, W. J., New Zealand Expeditionary Forces, France. Crook, John, 1 0 Prospect Terrace, Mount Eden. Cuff, J. C, Emerald Hill, Epsom. Culling, T. S., Ferry Buildings, Queen Street, Auckland. Culpan, W., Hesketh and Richmond, Wynd- ham Street, Auckland. Currie, J. C, 202 Queen Street, Auckland. Davis, Elliot R., Hancock and Co., Customs Street, Auckland. Davis, Ernest, Hancock and Co., Customs Street, Auckland. Dearsly, H., P.O. Box 466, Auckland. Dempsey, J., Newmarket. Dennin, John, care of Hon. E. Mitchelson, Waimauku. Dettmann, Professor H. S., University College, Auckland. Devereux, H. B., Waikumete. Donald, A. B., Queen Street, Auckland. Roll of Members. 371 Downard, P. N. R.. New Zealand Expedition- ary Forces, France. Duder, R. W., Devonport. Duncan, A., Railway Offices, Auckland. Duthie, D. W., National Bank of New Zealand, Wellington. Earl, F.. K.C., Swanson Street, Auckland. Edgerley, Miss K., Girls' Grammar School, Auckland. Edmiston, H. J.. Champtaloup and Edmiston. Queen Street. Auckland. Edson, J.. Waimarama, Tudor Street, Devon- port . Egerton, Professor ('. W.. M.A., University College, Auckland. Ellingham, W. R., Customs Street, Auckland. Elliot, G., Bank of New Zealand Buildings, Swanson Street, Auckland. Elliot. W., Bank of New Zealand Buildings, Swanson Street, Auckland. Ellis, A. F., Argyle Street, Ponsonby. Ellis, J. W., Hamilton, Waikato. Ellison, T.. Ellison's Buildings, Queen Street, Auckland. Endean. J.. Star Hotel, Albert Street, Auck- land. Endean, J., jun., Waitemata Hotel, Auckland. Entrican, A. J., Customs Street, Auckland. Entrican. J. C, Customs Street, Auckland Ewen, J. F. A., Sargood, Son, and Ewen (Limited). Victoria Street West, Auckland. Ewington, F. G., Durham Street, Auckland. Fairclough, Dr. W. A., Imperial Buildings, Queen Street, Auckland. Fallon, W., Union Buildings, Custoins Street. Auckland. Farrell. R.. Anglesea Street, Auckland. Fenwick, Dr. G.. New Zealand Expeditionary Forces. Fenwick, R., T. and S. Motrin, Auckland. Ferguson, A. M., John Burns and Co. (Li- mited), Customs Street, Auckland. Fleming, J., 1 42 Grafton Road, Auckland. Florance, R. S., Stipendiary Magistrate, Gis- borne. Fowlds, Hon. G., Queen Street, Auckland.* Frater, J. W., Stock Exchange, Auckland. Frater, Captain W., Manukau Road, Parnell. Garlick, G. C., Tonson Garlick (Limited), Queen Street, Auckland. Garrard, C. W., M.A., Education Offices, Auck- land. George, G.. Technical College, Wellesley Street, Auckland. George, Hon. S. T., St. Stephen's Avenue, Parnell. Gerard, E., Union Buildings, Customs Street, Auckland. Gilfillan, H., St. Stephen's Avenue, Parnell. Gillett, J., Hoiland and Gillett, Customs Street, Auckland. Gillies, A. W., Glenalvon, Waterloo Quadrant, Auckland. Girdler, Dr.. Khyber Pass Road, Auckland. Gleeson. J. C, Selwyn Lodge, Manukau Road, Parnell. Goldie. A.. Wallace Si reet, Ponsonby. Goldie, D., Breakwater Road, Auckland. Goldie, H., Breakwater Road, Auckland. Gorrie, H. T., A. Buckland and Sons, Albert Street, Auckland. Graham, A. G., Briscoe and Co., Customs Street, Auckland. Graham, G., Tudor Street, Devonport. Grant. .Miss .]., M.A., Devonport, Gray, A., Smeeton's Buildings, Queen Street, Auckland.* Gray, S., Mount Eden Borough Council Offices, Mount Eden. Gribbin, G., Nicholson and Gribbin, Imperial Buildings, Queen Street, Auckland. Griffin, L. T., Museum, Auckland. Grossmann, Professor J. P., M.A., University College, Auckland. Gimson. J. H., Mayor of Auckland, Church Road, Epsom. Gunson, R, W., New Zealand Expeditionary Forces. Haddow, J. G.. Wyndham Street, Auckland. Haines, H., F.R.C.S., Shortland Street, Auck- land. Hall, Edwin, Seacliff Road, Onehunga. Hallwright, Dr. G., Medical Chambers, Queen Street, Auckland. Halstead, E. D., Jervois Road, Ponsonby. Hamer, W. H., C.E., Harbour Board Offices, Auckland. Hansard, G. A., New Zealand Expeditionary Forces, France. Harbutt, S. J.. Selwyn Road, Epsom. Hardie, J. C, Hardie Bros., Queen Street, Auckland. Hardie y, J. W., Customs Street, Auckland. Harris, Louis, Huntly. Hawkins, Rev. Archdeacon H. A., Remuera. Hay, D. A., Montpellier Nursery, Remuera. Hay, Douglas. Stock Exchange, Queen Street, Auckland. Hayr, H. H., Union Bank Buildings, Queen Street, Auckland. Hazard, W. H., Queen Street, Auckland. Heather, H. D., Fort Street, Auckland. Herbert, T., Shortland Street, Auckland. Hemes, Hon. W. H., M.P., Wellington. Hesketh, H. R., Hesketh and Richmond, Wyndham Street, Auckland Hesketh S., Hesketh and Richmond, Wynd- ham Street, Auckland. Higgins, E., Market Entrance, off Queen Street, Auckland. Holderness, D., New Zealand Expeditionar}- Forces, France. Holland, J. J., City Road, Auckland. Herald Office. Queen Street, Horton, E., Auckland. Horton, H., Auckland. Houghton. ( Herald Office, Queen Street, \r.. New Zealand Shipping Company, Quay Street, Auckland. Howey- Walker, A.. Queen Street. Auckland. Hudson, C, Mount Eden Road, Auckland. 372 Appendix. Hunter, Ashley, C.E., Swanson Street, Auck- land. Hutchinson, F. R., St. Heliers. Hutchison, W. E., Nelson Street, Auckland. Ick-Hewins, Dr. T. J., Manaia, Taranaki. tnghs, Dr. R. T., New Zealand Expeditionary Forces. Isaacs, R. C; St. George's Bay Road, Parnell. Jackson. J. H., Customs Street, Auckland. Jackson, Thornton, Jackson and Russell, Shortland Street, Auckland. Johnson, H. Dunbar, 151 Newton Road. Johnson, Professor J. C, M.Sc, Litt.D., Uni- versity College, Auckland.* Johnston, Hallyburton, Morrinsville. Johnston, J. B., Stewart and Johnston. Wynd- ham Street, Auckland. Jones, J. D., P.O. Box 822, Auckland. Kenderdine, J., Sale Street, Auckland. Kent, B., Lower Symonds Street, Auckland. Kent, G. S., St. Stephen's Avenue, Parnell. Kissling. H. P., St. Stephen's Avenue, Par- nell. Kneebone, F., Mountain Road, Epsom. Knight, G., Asquith Avenue, Momit Albert. Laidlaw, R. A., Wyndham Street, Auckland. Lamb, J. A., Arney Road. Remuera. Lamb, S. E., B.Sc, University College, Auck- land. Lancaster, T. L., University College, Auck- land. Lang, Sir F. W., M.P., Hillsborough, One- hunga. Larkin, H., Harbour Board Offices. Auck- land. Lamer, V. J., Swanson Street, Auckland. Laurie, W. S., B.A., Laurie and Co., Customs Street, Auckland. Lawson, H. W., National Bank of New Zea- land, Queen Street, Auckland. Leighton, F. W., High Street, Auckland. Le Roy, E., 18 Waterview Road, Devonport. Leyland, W. B., Customs Street West, Auck- land. Leys, Cecil, New Zealand Expeditionary Forces. Leys, T. W., Star Office, Shortland Street, Auckland. Logan, R., jun., Government Insurance Build- ings. Queen Street, Auckland. Long, D., Farmers' Freezing Company, Break- water Road, Auckland. Long, W. H., Woodford Road, Mount Eden. Longuet, A. A., Palmerston Buildings, Queen Street, Auckland. Lowe, Dr. De Clive, Lower Symonds Street, Auckland. Lunn, A. G., Collins Bros., Wyndham Street, Auckland. McCullough, Hon. W., Thames. McDowell, Dr. W. C, Remuera. Macfarlane, J. B., Fort Street, Auckland. McFarlane, T., C.E., 301 Victoria Arcade, Auckland. Mcllraith, Dr. J. W., High School, Whangarei. Mcintosh, D. T., Railway Offices, Auckland. Mackay, G. J., Queen Street, Auckland. Mackay, J. G. H., Ellison Chambers, Queen Street, Auckland. Mackay. P. M., Wellesley Street, Auckland. Mackellar, Dr. E. H., Manukau Road, Par- nell. McKenzie, Captain G., Devonport. Mackenzie, Dr. Kenneth, O'Rorke Street, Auckland. McLaughlin, T. M., Hobson Buildings, Short- land Street, Auckland. Macklow, W. C, Mountain Road, Remuera. Macmillian, C. C, Remuera Road. Remuera.* MacMurray, Archdeacon G., St. Mary's Vicar- age, Parnell. McVeagh, R., Campbell and McVeagh, High Street, Auckland. Mahoney, T., Swanson Street, Auckland. Mains, W., Tram Terminus, Remuera. Mair, Captain G., Whakatane. Mair, S. A. R., Hunterville, Wellington. Major, C. T., King's College, Remuera. Makgill, Dr. R. H., Health Department, Wel- lington. Mander, F., M.P., Ponsonby. Marriner, H. A., New Zealand Insurance Com- pany, Queen Street, Auckland. Marsack, Dr., New Zealand Expeditionary Forces. Marshall, J., Te Atakua Road, Remuera. Mason, Mrs. F., Westoun, New Plymouth. Massey, Right Hon. W. F., M.P., Wellington. Matthews, H. B., Clonbern Road, Remuera. Mennie, J. M., Albert Street, Auckland. Metcalfe, H. H., C.E., Palmerston Buildings, Queen Street, Auckland. Miller, E. V., Chelsea, Auckland. Miller, E. W., Albert Street, Thames. Milne, J., John Chambers and Son, Fort Street, Auckland. Milne,. Miss M. J., Milne and Choyce, Queen Street, Auckland. Milne, Stewart, Milne and Choyce, Queen Street, Auckland. Milroy, S., Kauri Timber Company, Customs Street West, Auckland. Milsom, Dr. E. H. B., 18 Waterloo Quadrant, Auckland. Mitchelson, Hon. E., Waitaramoa, Remuera. Mitchelson, E. P., Motutara, Waimauku. Mitchelson, R., Dargaville. Morrison, A. R., Palmerston Buildings, Queen Street, Auckland. Morrison, W. B., Brunswick Buildings, Queen Street, Auckland. Morton, E., Customs Street, Auckland. Morton, H. B., One Tree Hill, Epsom. Mulgan, A. E., Star Office, Auckland. Mulgan, E. K, M.A., Education Offices, Auck- land. Murray, G. T., C.E., Public Works Office, Auckland. Murray, G. W., Omahu Road, Remuera. Myers, Hon. A. M., M.P., Campbell and Ehrenfried Company, Queen Street, Auck- land. Roll of Members. 373 Myers, B., Symonds Street, Auckland. Napier, W. J.; A.M.P. Buildings,, Queen Street, Auckland. Nathan, D. L., L. D. Nathan and Co., Short- land Street, Auckland. Nathan, N. A., L. D. Nathan and Co., Short- land Street, Auckland.* Neve, B., M.A., B.Sc, LL.B., Technical Col- lege, Wellesley Street, Auckland. Newton, G. M., Herald Buildings, Queen Street, Auckland. Niccol, G., Customs Street West, Auckland. Nicholson, O., Imperial Buildings, Queen Street, Auckland. Nolan, H. O., St. Stephen's Avenue, Parnell. Oliphant, P., 24 Symonds Street, Auckland. Oliver, W. R. B.,F.L.S., New Zealand Expedi- tionary Forces.* Osmond, G. B., Royal Insurance Buildings, Queen Street, Auckland. Ostler, H. H., Jackson and Russell, Shortland Street, Auckland Owen, Professor G., D.Sc, New Zealand Expeditionary Forces, France. Pacey, H. E., Hamilton Road, Ponsonby. Parr, C. J., C.M.G., M.P., Shortland Street, Auckland. Partridge, H. E., Albert Street, Auckland. Patterson, D. B., Ellison Chambers, Queen Street, Auckland. Patterson, Colonel G. W. S., Shortland Street, Auckland. Peacock, T., Queen Street, Auckland. Petrie, D., M.A., "Rosmead," Ranfurly Road, Epsom. Philcox, T., Philcox and Sons. Strand Arcade, Auckland. Philson, W. W., Colonial Sugar Company, Quay Street, Auckland. Pond, J. A., F.C.S., Queen Street, Auckland. Poole, G. S., Harbour Board Offices, Auckland. Porter, A. E., Porter and Co., Queen Street, Auckland. Potter, E. H., Tanfield, Potter, and Co., Queen Street, Auckland. Pountney, W. H., Fort Street, Auckland. Powell, F. E., C.E., Ferry Buildings, Queen Street Auckland. Price, E. A., Buchanan and Price, Albert Street, Auckland. Price, T. G., 109 Queen Street, Auckland. Pryor, S. H., 26 Pencarrow Avenue, Mount Eden. Pulling, Miss, Diocesan School, Epsom. Purchas, Dr. A. C, New Zealand Expedi- tionary Forces. Pycroft, A. T., Railway Offices, Auckland. Ralph, E. V., Arthur Street, Ponsonby. Ralph, W. J., Princes Street, Auckland. Rangihiroa, Dr., New Zealand Expeditionary Forces. Rawnsley, S., Quay Street, Auckland. Rawson, G. A., 31 Ferry Buildings, Queen Street, Auckland. Rayner, Dr. F. J., Queen Street, Auckland. Reed, J. R., K.C., Cleave's Buildings, High Street, Auckland. Reid, J., 43 Fort Street, Auckland. Renshaw, F., Sharland and Co., Lome Street, Auckland. Rhodes, C, " Ronaki," Remuera. Richmond, H. P., Arney Road, Remuera. Ridings, J. P., Collector of Customs, Customs Street, Auckland. Robb, J., Victoria Avenue, Mount Eden. Roberton, A. B., Heather, Roberton, and Co., Fort Street, Auckland. Roberton, Dr. E., New Zealand Expeditionary Forces. Robertson, Dr. Carrick, Alfred Street, Auck- land. Robertson, James, Market Road, Remuera. Roche, H., Horahora, near Cambridge, Wai- kato. Rolfe, W., Sharland and Co., Lome Street, Auckland. Rollett, F. C. Herald Offices, Queen Street, Auckland. Rowe, J., Onehunga. Russell, E. N. A., Russell, Campbell, and McVeagh, High Street, Auckland. Saxton, A. C, Pyrmont, Sydney. Scott, Rev. D., New Zealand Expeditionary Forces. Seegner, C, St. Stephen's Avenue, Parnell. Segar, Professor H. W., M.A., Manukau Road, Parnell. Shakespear, Mrs. R. H., Whangaparaoa. Shaw, F., Vermont Street, Ponsonby. Shaw, H., St. Arvans, Carlton Gore Road, Auckland. Simmonds, Rev. J. H., Wesley Training Col- lege, Epsom. Simson, T., Mount St. John Avenue, Epsom. Sinclair, A., Kuranui, Symonds Street, Auck- land. Sinclair, G., care of Pilkington and Co., Queen Street, Auckland. Skeet, H. M., Pencarrow Avenue, Mount Eden. Smeeton, H. M., Binswood, View Road, Mount Eden. Smith, Captain James, Franklin Road, Pon- sonby. Smith, H. G. Seth, Russell, Bay of Isalands. Smith, S. Percy, F.R.G.S., New Plymouth.* Smith, W. Todd, Brooklands, Alfred Street, Auckland. Somers, W. C, Russell and Somers, Customs Street, Auckland. Somerville, Dr. J., Alfred Street, Auckland. Somerville, J. M., Chelsea, Auckland. Spedding, J. G, Market Road, Remuera. Speight, W. J., Diocesan Office, Shortland Street, Auckland. Stanton, J., Fort Street, Auckland. Stewart, D. F., care of R. S. Lamb and Co., 32 Jamieson Street, Sydney. Stewart, J. W., Wyndham Street, Auckland. Stewart, John A., Kainga-tonu, Ranfurly Road, Epsom. Stewart, R. Leslie, Brown and Stewart, Swanson Street, Auckland. Streeter, S. G, Enfield Street, Mount Eden. 374 Appendix. Strevens, J. L.. New Zealand Expeditionary Forces. Suter, A., Lontis, Clonbern Road, Remuera. Swan, H. ('.. Henderson. Swanson, W., Queen Street, Auckland. Talbot, Dr. A. G., A.M.P. Buildings. Queen Street, Auckland. Taylor, W., Kempthorne, Prosser, and Co., Albert Street, Auckland. Thomas, Professor A. P. W., M.A.. F.L.S.. Mountain Road, Epsom. Thompson, Hon. T., Mount Eden. Thornes, J., Queen Street, Auckland. Tibbs, J. W., M.A., Grammar School, Auck- land. Tinne, H., Union Club, Trafalgar Square, London.* Tole, Hon. J. A., Queen Street, Auckland. Trounson, J., Northcote. Tudehope, R., Wellesley Street West, Auck- land. Tunks, C. J., Jackson and Russell, Shortland Street, Auckland. Upton, J. H., Bank of New Zealand Buildings, Swanson Street, Auckland. Upton, P., South British Insurance Company, Queen Street, Auckland. Upton, P. T., P.O. Box 878, Auckland. Upton, Selwyn, Star Office, Auckland. Vaile, E. E., Broadlands, Waiotapu. Vaile, H. E., Queen Street, Auckland. Virtue, P., Roller Mills, Quay Street, Auck- land. Wade, Lieut. H. L., New Zealand Expedi- tionary Forces, Palestine. Wake, F. W., Cleave's Buildings, High Street, Auckland. Walker, Professor Maxwell, University Col- lege, Auckland. Walklate, J. J., Electric Tramway Company, Auckland. AVallace, T. F., Waihi Gold-mining Company, Shortland Street, Auckland. Walters, J. R., Onslow Road. Kingsland, Auckland. Ware, W., Portland Road, Remuera. Warnock, J. A., 2 King Street, Grey Lynn. Watson, J., " Claengart," Remuera. Wells, T. U., Westbourne Road, Remuera. Westervelt, W. D., Honolulu. White, R, W., Wellington Street, Auckland. Whitley, \V. S.. Albert Street, Auckland. Whitney, C. A., Colonial Ammunition Com- pany, Auckland. Whittome, F., Carlton Road, Newmarket. Williamson, G, 81 Queen Street, Auckland. Williamson, J. G, Chief Postmaster. Auck- land. Williamson. J. D., Rukuhia, Hamilton.* Wilson, Andrew. District Surveyor, Hangatiki. Wilson, A. P., Victoria Arcade, Auckland. Wilson, C. A., Hume's Buildings, Shortland Street, Auckland. Wilson, F. W., Her