Sh | 92) ann ALBIAN STRATIGRAPHY ae, THE _ ANGLO-PARIS BASIN: P=; =) Sep | See | > 19 JAN1971 An “i Ona Wey ‘ - " i Pat wy a ‘ 7 f hy acy t 4, ; k ‘ ‘ > fl 4) 4 ¢ P "4 od . hike ’ : ; ‘ hs a. ‘ ‘ ‘ , i Fury 1 ; ,' Bs J heed ry: j ai A y om . ae _ BULLETIN OF BRITISH ‘MUSEUM. (NATURAL HISTORY) Poe he te RE | Supplement 8 Odes ane leet : LP. ee Ae ae weg © oe " Od Fav h Bay MIDDLE ALBIAN STRATIGRAPHY LIN. EEE ANGLO-PARIS BASIN BY HUGH GWYN OWEN 3 Plates, 52 Text-figures BULLETIN OF THE BRITISH MUSEUM (NATURAL HISTORY) GEOLOGY Supplement 8 LONDON : 1971 THE BULLETIN OF THE BRITISH MUSEUM (NATURAL HISTORY), instituted im 1949, 1s issued in five series corresponding to the Departments of the Museum, and an Historical series. Parts will appear at irregular intervals as they become veady. Volumes will contain about three or four hundred pages, and will not necessarily be completed within one calendar year. In 1965 a separate supplementary series of longer papers was instituted, numbered serially for each Department. This paper is Supplement No. 8 of the Geological (Palaeontological) series. The abbreviated titles of periodicals cited follow those of the World List of Scientific Periodicals. © Trustees of the British Museum (Natural History), 1971 World List abbreviation Bull. Br. Mus. nat. Hist. (Geol.). TRUSTEES OF THE BRITISH MUSEUM (NATURAL HISTORY) Issued 19 January, 1971 Price £6 MIDDLE ALBIAN STRATIGRAPHY IN THE ANGLO-PARIS BASIN By H. G. OWEN CONTENTS I. INTRODUCTION II, AcKNOWLEDGEMENTS III. DrEscRIPTION AND CORRELATION OF SECTIONS A. WEALD (i) FoLKESTONE : (ii) FOLKESTONE TO THE Mrpway (iii) MEDWay TO TROTTISCLIFFE (a) Paddlesworth (b) Trottiscliffe (iv) SEVENOAKS AREA (a) Sevenoaks Brick Works Ltd (b) St. John’s Brickyard (c) Dunton Green (d) Brasted ‘ (v) BrasTtED TO BUCKLAND (a) Westerham (b) Tandridge . (c) Buckland ‘ : (vi) BucKLAND TO UPPER BEEDING : (vii) UPPER BEEDING (viii) Hassocks To EASTBOURNE B. IsLe or WicutT, Dorset Coast (i) IsLE oF WIGHT (a) Redcliff (b) Rookley (c) Compton Bay (d) Ventnor to Niton (e) Blackgang . . (ii) BALLARD CLIFF TO OsmincTon ; (iii) THORNCOMBE BEACON TO BLACK VEN (iv) CoNCLUSIONS C. THE OUTCROP FROM DEvon TO BEDFORDSHIRE. (i) OKEFORD FITzPAINE (DORSET) (ii) VALE oF WARDOUR TO DEVIZES (WiLtsHIRE) (a) Vale of Wardour 3 (b) Maiden Bradley to Devizes (c) Caen Hill, Devizes (iii) Devizes TO THAME (Oxon) (a) Badbury Wick (Wiltshire) (b) Badbury to Thame MIDDLE ALBIAN STRATIGRAPHY (iv) THAME TO LEIGHTON-BUZZARD (BEDFORDSHIRE) . (a) Long Crendon (Bucks) (b) Haddenham (Bucks) (c) Aylesbury (Bucks) ; (d) Aylesbury to Leighton Buzzard E. BOREHOLE EVIDENCE : : (i) HAMPSHIRE BASIN (a) Winchester district : (b) Relationship of Winchester to Portsdown, the Weald, and the Isle of Wight : : (ii) Lonpon Basin, East ANGLIA, AND KENT (a) London Basin, S. Essex, AND N. Kent (b) The area of the Kent Coalfield F. SELECTION OF SECTIONS IN FRANCE (i) COMPARISON BETWEEN WISSANT AND FOLKESTONE (ii) THE OUTCROP FROM THE RIVER ORNAIN (MEUSE) To THE RIVER ARMANCE (YONNE) (a) Revigny-sur-Ornain (Meuse) (b) Pargny-sur-Saulx (Marne) (c) Les Cétes Noires (Haute Marne) (d) Courcelles prés Clérey (Aube) (e) La Vendue Mignot (Aube) (f) St. Florentin area (Yonne) (g) Summary (iii) PAys DE Bray (a) Villers St. Barthélemy . : (b) Forges-Les-Eaux, and St. Martin (iv) COMPARISON BETWEEN THE Pays DE CAUX AND THE IsLE-OF-WIGHT . (a) St. Jouin (b) Cauville (c) Octeville (d) Cap de la Héve (e) Summary, and comparison with the Isle- -of- -Wight IV. DEFINITION OF THE MIDDLE ALBIAN SUBSTAGE AND ITS ZONAL SCHEME IN THE ANGLO-PARIS BasIN A. HISTORICAL BACKGROUND B. THE ZONAL SCHEME OF THE MippLE ALBIAN IN THE ANGLo- Paris BASIN (1) DEFINITION OF THE BASE OF THE , MippLe ALBIAN (ii) THE SUBZONAL SEQUENCE (a) Subzone of Hoplites (I sohoplites) codentatus (b) Subzone of Lyelliceras lyelii . : 3 (c) Subzone of Hoplites (Hoplites) spathi (d) Subzone of Anahoplites intermedius (e) Subzone of Dimorphoplites niobe (f) Subzone of Mojsisovicsia subdelaruet (g) Subzone of Euhoplites meandrinus (h) Subzone of Euhoplites nitidus (i) Subzone of Anahoplites daviesi (iii) THE POSITION OF THE SUBZONE OF Dipoloceras cristatum (iv) THE ZONAL GROUPING : (a) The Zone of Hoplites (H.) dentatus (b) The Zone of Euhoplites loricatus IN THE ANGLO-PARIS BASIN 5 (c) The Zone of Euhoplites lautus : 4 : ‘ 129 V. LINKS WITH OTHER FAUNAL PROVINCES . 4 ; 130 A. THE BOUNDARIES OF THE HOPLITINID PROVINCE : : 130 B. LINKS WITH SEQUENCES OF OTHER COUNTRIES Z . 133 (i) Wrest PAKISTAN ; ; j ; : ; : 133 (ii) TETHYAN BELT ? : : : ‘ 5 : 133 (iii) ALGERIA : : : : . . ‘ ‘ 134 (iv) SOMALIA . : : 2 ; 5 : 2 : 134 (v) MapaGascaR . : F ; ! : 5 : 134 (vi) SoutH AMERICA : : : : : : : 134 (a) Colombia . : : : : : : : 134 (b) Peru . ; : : : - . ; : 135 (vii) Texas. : : : ; ‘ : j ‘ 135 (viii) CANADA . : : 3 ‘ ; Z , ‘ 137 (ix) GREENLAND. ; i : ; ; 5 : 138 (x) CONCLUSION . ; ; : ; : 138 VI. CONDITIONS OF DEPOSITION IN “ENGLAND : 139 (a) The Margins of the depositional basin in England and Northern France : 140 (b) The Structural Controls on Depositioni in Southern England 143 (c) Source of Middle Albian Sediments E : ‘ : 147 (d) The cristatum Subzone disturbance : : . : 148 VII. REVIEW OF THE AMMONITE FAUNA . : : ; : : 149 A. Description of new species. 5 : : : F 149 B. Stratigraphical list ‘ : : ; : : ‘ 152 VIII. REFERENCES ‘ : ‘ s : : : : 155 SYNOPSIS Much new information on the stratigraphy of the Middle Albian substage gained from sections in England and France is recorded, and where possible previous knowledge is revised, sufficient to stabilize the Ammonite Zonal scheme in the Anglo-Paris Basin ; d’Orbigny’s type area of the Stage. The succession in England is compared in detail with that of northern France by refer- ence to sections in the Pas de Calais, Meuse, Marne, Haute Marne, Aube, Yonne, Pays de Bray, and Pays de Caux, several misconceptions being eliminated. The ammonite zonal scheme is discussed in detail to provide the basis for international agreement of a zonal scheme for the faunal province, here termed the hoplitinid ammonite faunal province, of which the Anglo- Paris Basin is but a part. A brief review is made of the faunal links between the hoplitinid province, covering much of Europe, and neighbouring ammonite faunal provinces. These links occur essentially in the /yelli Subzone near the base of the Middle Albian, and in the cristatum Subzone at the base of the Upper Albian. The palaeogeographical implications of the distribu- tion of the faunal provinces are mentioned briefly. A study of the conditions of Middle Albian deposition in England shows that it tends to follow the pattern of Lower Albian and Aptian sedimentation in direct contrast to that of the Upper Albian where a different pattern pre- vailed. A review of the ammonite fauna terminates the work. RESUME L’auteur présente des nouvelles informations sur la stratigraphie de l’Albien moyen de l’Angleterre et de la France, afin d’établir le plan zonale des ammonites dans le bassin anglo- parisien, qui est la région typique de l’étage de d’Orbigny. Les couches de 1’Angleterre sont comparés en détail avec ceux-la de la France septentrionale. L’auteur donne tous les détail du plan zonale des ammonites, afin d’établir une province faunistique des ammonites hoplitinidés. L’auteur discute les liens faunistique entre la province des hoplitinidés et les provinces faunisti- que avoisinantes des ammonites. Ces liens ont bien surtout dans la sous-zone de /yelli auprés 6 MIDDLE ALBIAN STRATIGRAPHY de la base de |’Albien moyen, et la sous-zone de cristatum a la base de 1’Albien supérieur. Une étude de la méde de déposition de l’Albien moyen en Angleterre montre qu’elle imite la déposition de l|’Albien inférieur et Aptien, non pas celle-la de l’Albien superieur. L’auteur finit en passant en revue la faune des ammonites. I. INTRODUCTION TuE Albian Stage terminating the Lower Cretaceous has been divided into Lower, Middle, and Upper Substages. In England, the Lower Albian is represented within the top beds of the Lower Greensand and its junction with the overlying clays of the Gault ; the Middle Albian within the Gault, and by the Lower Gault where this division is recognisable ; and the Upper Albian by the Upper Gault and the contigu- ous Upper Greensand. Both the Middle and Upper Albian are represented within the Red Chalk facies. In northern France and the Paris Basin there is a similar lithological sequence, excluding a Red Chalk facies but including local lithological units in various areas such as the Sables de Puisaye flanking the northern area of the Massif of Morvan. This essentially common sequence reflects the closely comparable depositional environment which existed in the area of the Anglo-Paris Basin during Albian times. This Basin extended from the area of the Massif Central and the Vosges in the south to the English Midlands (text-fig. 51). It was flanked on the west by the Variscan massifs of Armorica and Cornubia, and on the east and north east by those of the Rhine State Mountains and the Ardennes. Late Jurassic—early Cretaceous deformation provided the basic structural pattern for Lower Cretaceous sedi- mentation which achieved its greatest geographical extent during Albian times. Middle Albian sedimentation followed this earlier pattern, but this changed in the Upper Albian due to tectonic disturbances at its start. The Basin was linked with the surrounding shelf seas north of the Ardennes, and with Tethys by means of the Morvano-Vosges strait. These sea-ways provided important migration routes for the fauna. In terms of absolute radiometric dates, the Albian is taken by Casey (1964 ; I99) to commence at 106 my B.P., and is considered to have had a duration of 6 million years. However, as that author clearly states, this is purely an arbitrary figure, the Cretaceous being divided into twelve equal time units corresponding to the twelve Stages. At present, therefore, there is no alternative but to use the relative units of time implied in the zonal schemes based on the faunal succession. Of these schemes, that based on the ammonites is the one which has been most thoroughly investigated, and the one that has led to much difference of opinion both national and international. A good deal of this disagreement is due to insufficient knowledge of the succession, despite the considerable number of papers which have been published. Within the lengthy bibliography on the English Albian two major works stand out ; the Memoir by Jukes-Browne (1900), and the Monograph by Spath on the Albian Ammonoidea (1923-43). The work carried out before 1900 in certain cases was truly excellent. For example, that of De Rance (1868) and Price (1879, 1880) at Folkestone, Newton (1897) at Okeford Fitzpaine, Dorset, and Keeping (1868) at Upware, Cambridgeshire. All this earlier work is ably summarised by Price and IN THE ANGLO-PARIS BASIN | Jukes-Browne and it is unnecessary to repeat it here. Jukes-Browne’s memoir included almost all the stratigraphical information then available obtained either by earlier workers, or by himself and William Hill for the Geological Survey. He provided a good picture of the stratigraphy of the Albian in England, and extended his study to make a brief examination of the Paris Basin. The accuracy of some of his and Hill’s field observations can still be demonstrated, and their reading of certain sections now long since vanished can be interpreted in the light of recent information with reasonable confidence. The first part of Spath’s Monograph appeared twenty-three years after the publica- tion of Jukes-Browne’s memoir, and it was completed over a period of twenty years. Its coverage was not complete, however, a fact which it is important to bear in mind. It consists of the description of ammonite faunas from the comparatively few localities that Spath himself collected from, or that were represented in museum collections upon which he largely worked. Other sections, although available during this period, were not apparently collected from by him and so, important parts of the ammonite fauna were not described. Nonetheless, this very important work pro- vided the basis and stimulus for the detailed stratigraphic work that was carried out during that period largely by officers of the Geological Survey, and the work that has been carried out since. The final part, published in 1943, contains a useful review of the stratigraphic work carried out in the period since I9g00. Since the completion of his Monograph, a great deal of new information has been obtained about Albian sediments in England. Contributions to our knowledge have been made by a number of authors, particularly by Casey and C. W. & E. V. Wright. Their papers and many others are listed in the bibliography and are discussed in the appropriate part of the text. In France, before Jukes-Browne’s Memoir was published, Charles Barrois wrote three important papers on the French Albian (1875a, 1875b, 1878). These, in associa- tion with d’Orbigny’s Paléontologie Francaise, provided a good picture of the strati- graphy and fauna of the Albian deposits of the Paris Basin. Barrois followed Hébert (e.g. 1875a) and others in including sediments, now classified as Upper Albian, within the Cenomanian. It is significant to note that Barrois already appreciated the magnitude of the break in the succession between what we now consider to be Middle and Upper Albian deposits in areas of the Paris Basin some 50 years before Kitchin & Pringle (1922a) recognised it in England. In his papers Barrois incorpor- ated the results gained by earlier workers such as Michelin, Leymerie, Raulin, Buvig- nier, Cornuel, Ebray, Hébert, Delatour, and others, and a comprehensive biblio- graphy is given by him (1878 ; 230-238). English workers such as Hopkins (1845), Topley (1868), Jukes-Browne & Hill (1896) and Jukes-Browne (1900) carried their researches into France, the latter authors providing new information particularly about the sequence in Normandy described previously by Lennier (1867). Much useful information was published in the period of 30 years which separated Barrois’ work from the publication of an important thesis by Jacob (1908). This thesis greatly increased our knowledge of the Aptian and Albian stratigraphy of the French Alpine area and adjacent Switzerland, the site of the Morvano-Vosges strait. In the following two decades, however, only a few papers were published. Of these, 8 MIDDLE ALBIAN STRATIGRAPHY Lemoine (1910) on the Yonne, Aube, and Haute-Marne, Ciry (1927) on the Céte d’Or, and Stieler (1922) on the coastal sections at Petit Blanc Nez, may be mentioned. In the period from 1930 until the war interrupted work, much new information was contributed by authors such as Breistroffer working in the French Alps (1931, 1933, 1936, 1940), P. & J-P. Destombes at Wissant (1938a) and in the Pays de Bray (1938b), Larcher (1937), Houdard (1933, 1940) and Marie (1939, 1941a) working in the Aube, Yonne, Marne, and Haute-Marne. Marie’s work on the Albian foraminifera and their zonal value included studies of sequences in the Pays de Bray (1941b) and Wissant (I94Ic). After the war, and with Spath’s Monograph completed, Breistroffer (1947) presented an important discussion of the ammonite zones of the Albian in France and England. Since then papers on various aspects of French Albian strati- graphy have been published. This more recent work is summarised, and much new information added, in the report of the Colloque sur le Crétacé inférieur held at Lyon in 1963 (1965). Of necessity the foregoing review is very brief, and only the more important works have been mentioned including those which give comprehensive bibliographies of earlier work. However, the relevant papers on the Albian of the Anglo-Paris Basin are discussed at the appropriate place in the text. Recent papers published in France and England show that disagreement exists on various aspects of the zonal scheme, and even the litho-stratigraphy. This disagreement is both national and international ; a serious state of affairs rendering distant correlation difficult (e.g. Young 1966). It is even more serious when one realises that here we are dealing with d’Orbigny’s ‘“‘ type area ”’ for the Albian Stage. An agreed zonal scheme can only be based on a detailed accurate account of the succession throughout a whole province, and inter-provincial correlation can only be accurately made once the stratigraphical successions are fully known. The object of the present work is to attempt to give this detailed information. Its presentation is the more urgent now that recent geophysical work indicates the closer proximity of Greenland, North America, and Europe in Albian times (e.g. Carey 1955, 1958, 1963, Bullard e¢ al. 1965), and the need to be able to compare in detail sequences in these areas with that of our own. The first part of this work, therefore, consists of the description and correlation of sections in England and France, and this contains much new information. The sections are shown graphically for easy reference. This descriptive part is sub- divided into convenient geographical areas. The second part consists of a detailed discussion of the ammonite zonal scheme given in Table 1 (p. 10), preceded by an historical introduction. This is followed by a review of the links between the Euro- pean ammonite faunal province and other areas, and in turn by a discussion of the conditions of depositionin England. The work is terminated by a brief review of the ammonite fauna, with descriptions of three new species of stratigraphic utility. II. ACKNOWLEDGEMENTS This paper is an abridged version of the thesis accepted for the Ph.D. degree of the University of London. It is a very great pleasure indeed to acknowledge the help IN THE ANGLO-PARIS BASIN 9 and support which has made the present work possible. In particular, I wish to thank the late Professor J. H. Taylor, and my supervisor Dr. J. M. Hancock for the considerable help and hospitality afforded to me as a research student at King’s College, University of London. Without the facilities provided by the various brick, tile, and cement companies, by national, regional and local authorities, and by private landowners both in England and France, all mentioned in the text, it would have been impossible to carry out the work at all. The following organisations and members of them have aided the work and to these my thanks are due: my colleagues in the Department of Palaeontology, British Museum (Nat. Hist.), in particular, Dr. H. W. Ball (Keeper), Dr. E. I. White (former Keeper), Dr. M. K. Howarth and Mr. D. Phillips, Dr. R. P. S. Jefferies, Mr. H. A. Toombs ; the Director of the Institute of Geological Sciences Dr. K. C. Dunham, Dr. V. Wilson (Assistant Director), Mr. S. C. A. Holmes (District Geologist S.E. District), Mr. R. V. Melville (Chief Palaeontologist) and Dr. F. W. Anderson, Dr. D. A. Gray (Water Department), Mr. L. S. O. Morris (Boring Department), Dr. R. Casey, and the members of their staff for making available outcrop and borehole material ; the Gas Council, Mr. P. Hinde (Head Geologist), and the late Professor V. C. Illing for per- mission to examine the Winchester and Cliffe groups of borings ; the Board of Directors of British Petroleum Ltd., Dr. P. E. Kent (Chief Geologist) and Dr. A. J. Martin, for making available borehole material and information ; Mr. S. B. Thomas (Ministry of Transport, Channel Tunnel Division), M. R. Malcor (Channel Tunnel Study Group), Mr. E. W. Jaccomb Hood (Channel Tunnel Site Investigation), and Mr. D. J. Carter (Imperial College) ; Mr. A. G. Brighton, Sedgwick Museum ; Brig- adier G. Bomford, Mr. F. H. Edmunds, and Dr. W. J. Kennedy, Oxford University ; Miss J. Royston, Buckingham County Museum ; and Mr. H. J. Bick (Central Electric- ity Generating Board). It is a pleasure to thank Mr. C. W. Wright for the loan of specimens and information. My special thanks are due to Dr. P. Destombes for his hospitality, and introduction to sections in the Pays de Bray and in the Yonneand Aube. M. J. Fourcher (Rouen) provided access at very short notice to the Bucaille Collection. I am indebted also to Dr. J. A. Jeletsky of the Canadian Geological Survey and Dr. Keith Young of the University of Texas. I am particularly grateful for financial aid from the following authorities : the Godman Fund, the Educational Authority of the London Borough of Bromley, the Central Research Fund of the University of London, the G. W. Young Fund of the Geologists’ Association, and my parents. I wish to thank my wife also for her help in various ways. III. DESCRIPTION AND CORRELATION OF SECTIONS A good deal of stratigraphic information can be displayed to advantage in the form of diagrams, and so all the lithological sections are presented as text-figures. Correlation charts, however, cannot provide the necessary accuracy when used alone, and require an accompanying text. Only the critical ammonites are mentioned in this section as a more detailed list and its stratigraphical distribution is given later. For ease of description the account is divided into convenient geographical areas to 10 MIDDLE ALBIAN STRATIGRAPHY which no structural significance should be attached : depositional controls on sedi- mentation will also be discussed later. The sections in the Weald are described first, then the Isle of Wight, Dorset coast, and the outcrop from Devon to the Leighton Buzzard area of Bedfordshire. The Albian sediments of the Leighton Buzzard area and of East Anglia are to be described elsewhere, but in no way do they affect the stabilising of the Albian Zonal scheme. Borehole evidence in southern England is TABLE I Ammonite zonal scheme of the Middle Albian adopted here and discussed in detail on pages 118-130. Substage Zone Subzone Upper Albian Mortoniceras inflatum (part) Hysteroceras orbignyt (part) Dipoloceras cristatum” Anahoplites daviesi Euhoplites lautus Euhoplites nitidus Euhoplites meandrinus Middle Euhoplites loricatus™ Mojsisovicsia subdelaruei Albian Dimorphoplites niobe Anahoplites intermedius Hoplites (Hoplites) spathi Hoplites (H.) dentatus Lyelliceras lyelli® Hoplites (‘ Isohoplites’) eodentatus Lower Douvilleiceras Protohoplites puzosianus Albian mammillatum Otohoplites raulinianus (part) (part) (1) Formerly included in the /autus Zone sensu Spath (e.g. 1941 ; 668). (2) First recognised by Owen (1958 ; 162). (3) Approximately equivalent to the benettianus Subzone of Spath non De Rance (1868). (4) In better developed sequences in France (Pays de Bray, Aube), this index fossil does not range up to the base of the eodentatus Subzone. then considered before attention is turned to the Paris Basin. A detailed compar- ison is made between thesections at Folkestone and Wissant (Pas de Calais). Selected sections in the Meuse, Marne, Haute Marne, Aube, Yonne, and in the Pays de Bray, are described followed by a comparison of sections in the Pays de Caux with the Isle of Wight. The ammonite zonal and subzonal scheme employed in this account is given in Table 1 above. @ HERTFORD @ WENDOVER @ST ALBANS ve @ CHELMSFORD 4 @ HIGH WYCOMBE ye > SOUTHEND 23] 3 P PORTLAND BEDS o Chiswick LONDON Gault K KIMMERIDGE CLAY THAMES Outcrop Symbols Upper Greensand © Richmond C CORALLIAN BEDS SHEERNESS e ana orem Leen sand ©Egham( Virginia Water) Paddlasworth © Addington <7 Purbeck Dunton Green, co Jurassic ‘Sevenoaks BW. @ SEVENOAKS A249 Clover Leaf m Squerryes Tandridge GUILDFORD ee A fs et It a pend @ REDHILL, — ~~ ye = -Buckiong \=— @ TUNBRIDGE WELLS @ HORSHAM THE WEALD Junction —~7 once OUNGENESS Horton Halt @ BRIGHTON oro os @ CANTERBURY =I —s RAMSGATE Folkestone EASTBOURNE SELSEY BILL — Beachy Head = ——— _—_—— 30 Fic. 1. Sketch map of the Weald and adjacent areas showing positions of sections and boreholes discussed in the text. IN THE ANGLO-PARIS BASIN GE A. Weald The Gault describes a narrow outcrop at the foot of the Downs from Folkestone in the east, around the northern, western and southern borders of the Weald to reach the sea again at Eastbourne (text-fig. 1). Deposits of Middle Albian age are present throughout and reach their greatest known thickness in Sussex. No section has yet provided a complete and relatively uncondensed sequence. Although the greatest degree of representation is to be found in the Folkestone area of Kent and between Steyning and Ringmer in Sussex, even at these localities condensation at certain horizons is very marked. Fortunately, further west in the northern Weald some condensed horizons are greatly expanded, but this is offset by truncation westwards of deposits of the higher subzones of the Middle Albian due to tectonic movements and associated erosion within the cristatum Subzone. (i) FOLKESTONE In response to the general north-easterly dip, the Gault appears above the Folke- stone Beds at the top of East Cliff, where it overlooks the harbour, and declines to the shore in East Wear Bay. Copt Point is the promontary at the NE. end of East Cliff at the entrance to East Wear Bay, and it was shortly after a substantial cliff-fall in 1959 that the section given in text-fig. 2 was measured. By far the bulk of the fossils, for which the Folkestone Gault is famous, were collected from the foreshore exposures in East Wear Bay (East Weir Bay of early authors), but due to cliff and shore stabilising work carried out by British Railways, these sections are now hidden beneath beach-sand (see Bisson in Smart ef al. 1966 ; 293-296). It is worth recording that in the period between 1948 and 1956 when remedial work obscured the sections, a large slice of Gault extending from the top of Bed III to the base of Bed X could be seen from the area now covered by the western half of the Toe-weighting to about 100 yds west ofit. This slice was not greatly disturbed within itself, but at the line shown by Bisson (Smart et al., 1966 ; fig. 17, p. 294) the dip was in the order of 70°—80° landwards. The Folkestone Gault has attracted the attention of many workers because of the intrinsic beauty of its fossils. The early history of research is ably summarised by Price (1879, 1880) whose bed notation is still broadly used today. De Rance (1868), however, was the first to divide the Gault into Lower and Upper Divisions and to subdivide them further into eleven Beds. Price (1874, 1875) accepted De Rance’s Upper and Lower Gault and also recognised eleven Beds but these did not coincide with those of De Rance. De Rance later (im Topley 1875 ; 146) accepted the bed notation of Price but they do not coincide lithologically. Jukes-Browne subse- quently modified Price’s account, and it is his reading of the section which has been accepted by subsequent workers (1900 ; 69-83). Spath (1923-43) drew heavily on the well preserved ammonite fauna of this locality, and indeed, the degree of repre- sentation in his Monograph is largely a reflection of the high degree of representation within the section itself. Spath (1923a, b, c ; 1926b), like Jukes-Browne (1900 ; 45), expressed his zonal scheme for the Middle and Upper Albian essentially in terms of the lithological sequence at Folkestone. N MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ft Ins M § (iii) Seam of phosphatic nodules and many partly phosphatised fossils in grey clay = 34 with crushed shells. ~ VIII[G) Grey clay with shells mainty of Inoceramus sulcatus. 2 10-11 (i) Seam of black phosphatic nodules in grey clay. i 2 10 a 2 > J » 9 VII | Grey clay with shell seams containing pyritised fossils and scattered ° phosphatic nodules. 4 3 8 = = c VI Mottled lignt-grey clay with numerous dark grey burrows; occuring as fo) irregular tenticles in dark grey clay. Vv Midgrey burrowed clay with occasional scattered brown phosphatic nodules, 67 7 iii) Abraded biack phosphatic nodules, often fragments of ammonites,in grey clay. 1-2 IV } fui) Bark grey shelly clay. 4 Gi) Seam of bivalves, part-phosphatised fossils,and buff phosphatic nodules. va 1 6 a fe) | II Fawn-grey clay with shell seams and partly phosphatised fossils, Occasional & lenticles of ferruginous merlstone occur, s 5 (iv) Clay like II(ii) passing at the top by lenses into Bed ill. 11 (iii) Seam of blackisnh phosphatic nodules in dark grey clay. (ii) Dark-grey clay, black when wet,with seams of crushed shells and scattered osphatic nodules. crushed & part (vii) Dark-grey slightly silty shelly clay. (vi)Gritty grey clay becoming more glauconitic and gritty downwards; sparsely tossiliferous and with occasional thin seams of phosphatic ‘clots” spathi (v) Large phosphatic nodules mainly casts of ammonites in shelly glauconitic loam — ‘dentotus nodule bed? (iv) Highly glauconitic loam with a few blackish atic nodules. (ii) Scattered spherical septarian phosphatic nodules. lauconitic loam with scattered lumps of blackish phosphate and a few osphatic nodul h <- 3 ord intermedius | n nw = ny w + a lyelli ent. . 10 Fic. 2. Cliff section of Lower Gault a few yards NE of the sewer, Copt Point, Folkestone, Kent. IN THE ANGLO-PARIS BASIN 13 Since Spath completed his Monograph, our knowledge of the Lower Gault at Folkestone has been increased by Casey (1950) and the author (Owen 1958 ; 1963a). Bisson (in Smart, Bisson & Worssam 1966 ; 56-58) has given an account of the section, but this is based essentially on Jukes-Browne. The revised section of the Lower Gault, given in part by me in 1963 (1963a ; 36-38) and in full in text-fig. 2, is the first new account since Price (1880). It is slightly thicker than that of Price, but this is probably due to his section being further out from the modern cliff-line, the seaward slope of the land at Copt Point producing a slightly thinner sequence due to creep at the cliff of Price’s day. Casey (1950 ; 272-3) divided Bed I into four sub-divisions corresponding to (i) the ‘Sulphur Band’, (ii) the ‘Greensand Seam’, (iiia) the dentatws nodule bed, and (iiib) the remainder of the clays. He classified the whole of the ‘ Greensand Seam ’ with the inaequinodum Subzone, later (e.g. in Worssam et al. 1963 ; 59) replaced by the index Hoplites (Isohoplites) eodentatus. The dentatus nodule bed and the lower part of the overlying clays were, following Spath, classified with the spathi Subzone, and the upper part of Bed I with the intermedius Subzone. He concluded that the benettianus Subzone (i.e. the lyella Subzone) was probably absent (see also 7» Worssam et al., 1963 ; 59). Subsequent work has shown that Casey’s subdivisions are too broad and a more detailed notation is given by me (Owen 1963a ; 36-38, 49) and in text-fig. 2. Fossils are rare in the ‘Greensand Seam’. The specimens of Hoplites (Isohoplites) in the Institute of Geological Sciences (GSM 83165-6 Spath Coll.) are angular frag- ments like the nodules of I(ii) which is here classified with the eodentatus Subzone. Bed I(iii) has not yielded fossils to me, but in I(iv) at a depth of 2 inches (0-05 m.) beneath the dentatus nodule bed, I have collected, apart from the specimen of Hoplites (H.) cf. bayle: Spath figured by me (1963a ; 37, pl. 3, fig. 3), a fragment of Beudanticeras sp. indet. together with one specimen of Neohibolites minimus (Miller) and a few indigenous and very delicate bivalves. The association of Hoplites (Hoplites) and Beudanticeras indicates the lyell1 Subzone. From a knowledge of the lyella Subzone successions at Small Dole (p. 35), Swindon (p. 61) and the Aube (p. 91), the writer is firmly convinced that the specimens of Hoplites (H.) aff. benettianus which occur rarely in the spherical phosphatic nodules immediately beneath the dentatus nodule bed (Owen 19632 ; 37, pl. 3, figs. 1a, b ; 2a, b) are of late lyelli Sub- zone age. The presence of this Subzone at Folkestone is not surprising because it is well represented in the Gault of the Guilford (Waldeshire) Colliery shaft (p. 76) about 7 miles (11-25 km.) from Copt Point, and in the Aycliff boring (p. 78). The classification of the remainder of Bed I has been discussed by the writer already (Owen 1963a ; 37-38, 49), and it is only necessary to question one statement made by Casey (tn Hancock 1965 ; 247) that Anahoplites intermedius comes in a foot or two above the spathi nodule bed as a minority element in a fauna still dominated by Hoplites. If this were the case, then the Folkestone section would be unique. Species of Hoplites (H.) occur crushed in Bed I (vi) up to a height of 3 feet 2 inches (0-96m.). Higher up, ammonites are absent or very rare until one reaches the base of I (vii), at which level Anahoplites intermedius appears. At Folkestone, as at most other localities in the Weald, there is a gap in the ammonite fauna between un- I4 MIDDLE ALBIAN STRATIGRAPHY doubted deposits of spathi and intermedius Subzone age. There is no break apparent in sedimentation, but the only common fossils are large Inoceramus concentricus. At localities such as Petersfield (Sussex p. 34), Osmington (Dorset p. 51), Devizes (Wilt- shire p.60),andtoapointalsoin thesouthern part of the Paris Basin (pp. 88,93, 97) this gap in the Weald sequence is filled. There is indeed the association of Anahoplites and Hoplites (H.) but the forms of Anahoplites are very distinct and include A. grims- dalei sp. nov. and A. osmingtonensis sp. nov. ; forerunners of the evolutus-intermedius- praecox group. Hoplites (H.) continues on into the intermedius Subzone but is a very subordinate element in the fauna. The classification of the remainder of the Lower Gault at Folkestone by Spath has seen only a few modifications (Owen 1958 : 1960 ; 376-7). Spath pointed out (1926b; 421) that the divisions between Subzones do not always coincide with the junction between beds. The details of Bed I (vi—vii) given by the writer in 1958 were taken from what are now obviously disturbed sections, but were then the best available, and should be discounted. The account given in 1963 was taken from a perfect section. Bed I (vii) and the whole of Bed II up to a level 3 inches (0-70 m.) below its top, are classified with the intermedius Subzone. The bulk of the ammonites are crushed and consist essentially of species of Anahoplites such as A. intermedius, A. praecox,and A. mantelli. Partly phosphatised ammonites occur in Bed II (i) and pyritic specimens occur very sparingly among the numerous crushed fossils in II (ii). The fauna of these three subdivisions is very uniform, but in II (iii) we see the intro- duction of a particularly coarse development of A. praecox, and in II (iv), where ‘solid’ pyritic fossils are more common, Ewhoplites pricet Spath is a very character- istic form. Dimorphoplites niobe Spath, already present in the imtermedius Subzone, becomes common in the shell seam about 3 inches (0-076 m.) below the base of Bed III at which level Anahoplites of the praecox-intermedius group quite suddenly ceases to be im- portant. D. mobe, together with A. planus and A. splendens then characterises the whole of Bed III, within the upper 2 to 3 inches (0:051-0-076 m.) of which, part or wholly phosphatised fossils with the nacreous shell occur sparingly. Bed IV (i) does not mark a great break in the sequence although semi-derived phosphatic fragments of fossils do occur. D. niobe, A. planus and A. splendens still occur but the fauna becomes more diversified and Mojsisovicsia subdelaruei M. remota and M. spinulosa (Spath) appear as infrequent but highly characteristic species. These species of Mojsisovicsia occur indigenous in both IV (i) and (ii) which are classified with the subdelaruet Subzone (Owen 1960 ; 376). Bed IV (iii) marks a greater period of erosion and its characteristic ammonite fauna was listed by Owen (1958 ; 157). This bed, together with the basal 2 inches (0-051 m.) of Bed V which contains the same fauna is classified with the meandvinus Subzone. Casey (in Smart, Bisson & Wor- ssam 1966 ; 109) and in effect Milbourne (in Hancock 1965 ; 247) state that Euhoplites meandrinus Spath occurs outside Bed IV (iii) and the basal part of Bed V. However, the author has never seen a specimen, either in the field or in the collections, from any other bed. Spath’s original (BMNH, C 32306) was a pyritic specimen, now decom- posed, which with very little doubt came from the basal part of Bed V, as Spath thought likely (1930b ; 271). SUBZONES E STREET WYE BRABOURNE — SELLINDGE SANDLING FOLKESTONE) cristatum PADDLESWORTH A249 CHRISMILL = EYHORN : Par fieseaies STED DUNTON GREEN ST JOHN’S SEVENOAKS — FORD PLACE DLE: A249 SSI ss ts > TANDRIDGE SQUERRYES BRASTED senna 6 peace, cooeest] 6 leegsees @ 5 ta ee aan ica =daviesi a 7——? 2 2——— fesrea, 6 v= pease v Ren PE ni. Ar ieee : ‘ jesi Bell I eee 5") —} O00 ie (apa feliii) Fe ci) ——— i) 2 2 daviesi F “|s@ [onan sa ——— " j ?7—___, a —— —————t (J ee + eet C(ii) : ? ————— ——? —————? ‘soa: fracaand 1 eee) nitidus ? a2] 4 : rp V 4+5 MSS 50) hus 5 (i) aN oe OD) A cu ? a ov ? > 4 i P ; ; [oe = —-, ? ?7——__2 | / PS ee Ly ae ee ran EH aes foe ? ? ? 2 ? ? L faeaeaeal hess —~ SS a 3 ee B | P ING SE intermedius Subzonal correlation lines Lithological correlation lines Fic. 3. Correlation of sections in Kent and east Surrey. IN THE ANGLO-PARIS BASIN 15 The sudden change from a deeply sulcate to a channelled venter in Euhoplites which occurs at a height of 2 inches (0-051 m.) up from the base of Bed V was taken by the writer to mark the base of the mitidus Subzone and the lautus Zone (Owen 1958 ; 157-8, 162). There are a few scattered phosphatic nodules at this level and a small break in deposition is further suggested by the sequence at Ford Place, Trottiscliffe (p. 22). The remainder of Bed V together with Bed VI are classified with the mitidus Subzone and yield a typical fauna. Apart from the highly burrowed nature of the clay, Bed VI is also characterised by particularly tuberculate examples of Dimor- phoplites of the parkinsoni type. The lower part of Bed VII, previously classified with the daviesi Subzone, in fact still contains a nitidus Subzone fauna and must be classified with that Subzone (Owen 1960 ; 376). Anahoplites daviesi does not appear in the sequence until a height of about 5 feet (1-524 m.) is reached, and this and closely related forms characterise the remainder of these clays of Bed VII which are classified with the davies: Subzone. Bed VIII at the summit of the Lower Gault was classified by Spath and subsequent authors with the cristatum Subzone here included in the Upper Albian (inflatwm Zone). The depositional history of Bed VIII is complex. The lower nodule bed VIII (i) represents a moderate break in deposition, and its fauna includes the bivalves Inoceramus concentricus, I. sulcatus subsulcatus and I. sulcatus, and the ammonites Dipoloceras bouchardianum (d’Orbigny) and Beudanticeras beudantt (Brongniart). At Wissant (p. 85) on the French coast 22 miles from Folkestone, the equivalent of Bed VIII (i) is represented by the clays of Bed 12 (v) in which a coarse form of J. concentricus at the base soon passes into the subsulcatus stage to achieve the sulcatus form at the top. This bed also yielded the holotype of D. bouchardianum and B. beudanti also occurs. It is, however, apparent that some material of late daviesi Subzone age is also present in the remanié fauna of Bed VIII (i) at Folkestone. This element can be demonstrated by the occurrence of very coarse developments of Anahoplites of the davies: group and typical I. concentricus. A detailed discussion of Bed VIII and its fauna is out of place here but it is essentially of cristatwm Subzone age. The uncondensed sequence at Wissant indicates that the incoming of the typical fauna of the cristatwm Subzone was quite rapid. This fauna continues on into the basal few feet of Bed IX which will also have to be classified with the crvistatum Subzone. Bed VIII is in all truth a junction bed as the early workers recognised. (u) FOLKESTONE TO THE MEDWAY No complete sequence in the Lower Gault has been seen between Folkestone and Chrismill Lane, Thurnham, on the Maidstone By-Pass, a distance of 29 miles (46-67 km.). What little information is available is ably presented by Smart, Bisson & Worssam 1966 (Folkestone to Westwell), Worssam ¢é¢ al., 1963 (to a few miles W. of Maidstone), and Dines, Holmes & Robbie 1954. A little additional information is given here, and the correlation of the sections is shown in text-fig. 3. It is apparent that the sequence seen at Copt Point has changed already by Elenden Gardens, Cheriton (Spath 1923c ; 141-2) but unfortunately no precise 16 MIDDLE ALBIAN STRATIGRAPHY details of this section were recorded. Bisson im Smart e¢ al. (1966 ; 100) has described the Folkestone Brickworks section at Cheriton (TR 205376) in which I suspect that the lowest 2 feet 6 inches (0-762 m.) recorded as ‘ Dark-grey slightly micaceous blocky clay with occasional phosphatic nodules’, underlying the basal cristatum nodule bed, is of daviest Subzone age as at Copt Point, and at Wye near Ashford. However, I did not see this part of the succession. At Sandling Junction (text-fig. 4) the fauna of Bed 9 classified with the spathi Subzone is identical to that of Division A in the Maidstone By-Pass (Owen 1960 ; 372), and so, the age of the dentatus nodule bed has already changed at the outcrop within 5 miles (8-05 km.) of Copt Point (Owen 1963a; 49-50). No fossils have yet been found in the underlying glauconitic loams of Beds 4-8. Bed 8 (of Worssam 1966 ; 99) at File’s pit in Swan Lane, Sellindge (TR 11853915) is the equivalent of Bed 9 at Sandling, and Bed 6 yielded the specimen of Hoplites ? recorded by Worssam. Bed Lithology Weathered grey clay. ' | Phosphatic nodules mainly fragmentary casts of Hoplites(H.), Grey slightly glauconitic clay. Scattered phosphatic nodules in grey slightly glauconitic clay. —_— | Mottled yellow, green, grey, glauconitic loam becoming more ! argillaceous upwards. ?eodentatus—lyelli spathi Shattered ferruginous phosphatic nodules in loam. Mottled glauconitic loam with occasional phosphatic nodules. Shattered fterruginous phosphatjc nodules in grey loam. Dense band of phosphatic nodules in lenticular cemented grit, | puzosianus Yellowish sand with small scattered phosphatic nodules Fic. 4. Section in Gault-Lower Greensand junction beds at Folkestone Quarries Ltd’s Sandling Sandpit, c. 150 yds. NW. of Sandling Junction railway station, Saltwood, Kent (TR 14703690). This specimen (GSM., CW 855) is a definite Hoplites (H.) but there is no other indication of the age of the sediments overlying the puzosianus Subzone sediments. The principle bed of phosphatic nodules in the spathi Subzone sediments at the Granary Court Sand pit at Brabourne (TR 09004005) is also on the same horizon as that of Bed 9 at Sandling. At Brabourne, in the area where Hill (in Jukes-Browne 1900 ; 84) records a section, the former Ashford & Naccolt Brick, Tile & Potteries Ltd., dug shallow pits in higher beds of the Lower Gault about 800 yards (731 m.) a little north of west from Park Farm (TR 08904065). About 8 feet (2-43 m.) of weathered brownish clay streaked with ferruginous matter was to be seen beneath superficial deposits. Towards the top of the clays a disturbed seam containing phosphatic nodules yielded fragments of the following :— Anahoplites planus (Mantell), A. pleurophorus Spath, Dimorphoplites aff. niobe, D. cf. doris Spath, Euhoplites cf. subtuberculatus Spath late mutation, E. microceras IN THE ANGLO-PARIS BASIN 17 Spath late mutation, Hamites tenuicostatus Spath, Inoceramus concentricus Parkin- son. The assemblage indicates the subdelaruei Subzone as restricted here and by the writer in 1960, which coincides with the term ‘ lower subdelaruet Subzone’ given by Smart (im Smart, Bisson & Worssam 1966 ; 98). The age of the underlying clay was not determinable, but the whole sequence is similar to that of the Maidstone By-Pass (text-fig. 3). Smart records cristatwm Subzone fossils from a similar shallow working 300 yds (274 m.) to the NNW. In the Ashford Brickworks Ltd pit (formerly the Ashford & Naccolt Brick, Tile & Potteries Ltd) situated 700 yds NW. of Sillibourne Farm and about 110 yds ENE. of Blackwall Farm, Wye (TR 04954445) the upper beds of the Lower Gault have recently been exposed (text-fig. 5). This is the pit recorded by Cornes (7m Dewey et al., 1925 ; 263-4) as “ New Nackholt’, and by Smart at TR 049445 (1966 ; 98). Bed Lithology Ft Ins M Dense seam of phosphatic nodules and phosphatic tragments of fossils. (iv) Dark grey clay shelly witn part phosphatised fossils particularly inthe basal inch. (iii) Dark grey clay with few fossils and occasional scattered phosphatic nodules, Gi) Bed of scattered brownish phosphatic nodules in dark grey clay. (i) Dark grey clay. ?nitidus daviesi cristatum ~~ — => <— ¢—_— seen to Fic. 5. Upper beds of Lower Gault at Naccolt Brick Works (Ashford Brickworks Ltd), 700 yds NW. of Sillibourne Farm and c. 1100 yds ENE. of Blackwall Farm, Wye, Kent (TR 04954445). Anahoplites daviesi and A. daviesi ornata appear at a depth of ro inches (0-254 m.) below bed 2, the cristatum nodule bed, and the remainder of the clay up to bed 2 is classified with the daviest Subzone. Whether the lower part of the exposed clays of bed 1 is also of daviesi Subzone age is not certain. Only a single nodule bed (bed 2) here represents Bed VIII at Folkestone and its character and fauna is almost identical to that of Division D in the Maidstone By-Pass (Owen 1960 ; 374). The section recorded by Hill (7m Jukes-Browne 1900 ; 84) at Kennington, the ammonites from which were re-determined by Casey (im Smart et al., 1966 ; 97), apparently showed some Lower Gault, but it is at present impossible to interpret the sequence. Unfortunately the sections recorded between Wye and Hollingbourne are in- sufficient to determine the succession. The preservation of the ammonites from Westwell Leacon and Kennington preserved in the Institute of Geological Sciences suggests nodule beds about the same horizon as beds C (ii) and D in the Maidstone By-Pass. The pit at Eyhorne Street, Hollingbourne, described by Hill (im Jukes- Browne 1900 ; 85) was alleged to show beds spanning the Lower Gault-Upper Gault junction. However, Casey (in Worssam et al., 1963 ; 59) has re-determined the fossils collected from this pit and demonstrated that the section was wholly in the Lower Gault and that Hill’s reading of it was incorrect. If one compares the section given B 18 MIDDLE ALBIAN STRATIGRAPHY Div. | Lithology § Ft Ins So Dense seam of blackish phosphatic nodules and fossils in 4 bluish grey clay. Nodules tend to divide Into two seams. S 3-4 a 3 (iil) Bluish-grey clay becoming darker upwards, with brownish |= partings and pockets of limonite after pyritised fossils. = Occasional phosphatised fossils occur with the shell WY 4 ° especially ata level 4inches below the top. A scattered = line of small buff phosphatic nodules occurs Sinches above b the base. 2 € e . . . . . e — —' (il) Bed of chocolate-brown phosphatic nodules in dark fawnis Sud ae are a tee jet grey: clay. ° 3 (1) Darkish, rather fawn-grey clay about 1 foot in thickness with shell seams and scattered phosphatic nodules, 6 0 underlain by dark-grey shelly clay passing down into light speckled fawn-blue-grey clay with sporadic lenticles of ferruginous marly clay and marlstone near and at the base. niobe (ii) Dark blue-grey clay with shell seams, lightening In 2 2 colour towards the top. ee ses - @ea+ Pe ae — 2 (it) Seam of irregular—shaped phosphatic nodules. ” 3 v a € x a & (i) Grey slightly fawn clay with many shell seams and bands of burrowed clay passing down into three feet three inches of greenish grey clay becoming progressiv- ely darker and more glauconitic downwards The clay is blocky with yellowish partings and contains seams of scattered incipient buff phosphatic nodules at ° heights of 2feet Binches, 3 feet Qinches, 4 feet 6 inches, 6feet 3inches and 8 feet 8 inches. < J Q ” Bed of blackish pho gnats nodules, some septarian,!n highlyX\ glauconitic clay with some crushed fossils. Glauconitic sandy clay, becoming sandier below. Piyelli’ : Fic. 6. Lower Gault sections at NW. quadrant of A 249 clover leaf, Maidstone By-Pass (East Section) M 20, extending from a point 585 yds NE. of the Chiltern Hundreds public house to the A 249, Boxley, Kent (TQ 77805745). IN THE ANGLO-PARIS BASIN 19 by Hill with that of the Maidstone By-Pass (Owen 1960 ; 369-371 and text-fig. 6 herein) it can be seen that the sequence exposed at Eyhorne Street included parts of the equivalent of Divisions B and C which appear to be identical to that of the By- Pass. There is nothing further to add to my account of the sections exposed during the construction of the Maidstone By-Pass motorway (M20) (Owen 1960), except for an unfortunate omission of a complete sentence in my reply to the discussion of my paper by Gray (1962 ; 469). The missing sentence read, ‘ As seen in the sections, the Tertiary faulting affects the beds [in the A 249 clover-leaf] in the following manner.’ Without this sentence there is the implication that the faulting is intra-Albian which it certainly isnot. The correlation of the sections is shown in text-fig. 3, and it can be seen that the stratigraphical succession is very uniform. (ii) MEDWAY TO TROTTISCLIFFE (a) Paddlesworth West of the Medway, the outcrop changes direction through an arc of about 12° but no complete sequence is seen until one reaches the Ford Place clay-pit, Trottiscliffe, where the Middle Albian sequence is thicker than at the Maidstone By-Pass. How- ever, in the early months of 1968 the Associated Portland Cement Manufacturers clay pit at Paddlesworth, which has for many years shown an important Upper Gault sequence, was cut further south exposing the higher part of the Lower Gault. The Middle Albian sequence is shown in text-fig. 7, and its correlation with the Maidstone By-Pass and Ford Place in text-fig. 3. The basic similarity with the sequence at Ford Place from the middle of Division 4 permits the use of the same divisional enumeration. By analogy with Ford Place, the 3 feet 6 inches (1-067 m.) of clays at the top of Division 4 at Paddlesworth are almost certainly of swbdelaruet Subzone age. They contain numerous Inoceramus concentricus and Hamites tenuicostatus as at Ford Place, but no specimens of Mojsisovicsia are yet to hand. These clays represent an expansion of nodule bed C (ii) at the Maidstone By-Pass. Bed 5 (i) contains a typical meandrinus Subzone fauna and the sediments up to the top of 5 (vii) are also classified with this Subzone. 5 (i) corresponds exactly to 5 (i) at Ford Place but does not contain phosphatised fossils with the shell preserved as at the latter locality. 5 (ii-vi) correspond to 5 (ii-iv) at Ford Place and 5 (vii) is the direct equivalent of 5 (v). In general the sequence is slightly thinner at Paddlesworth than at Ford Place, but it is much thicker than that seen at the Maidstone By-Pass where the equivalent sediments are but 2 feet 7 inches (0-787 m.) thick. The sediments of Jautus-Zone age at Paddlesworth 5 (viii) are 2 inches (0-051 m.) thicker than at Ford Place 5 (vi), and 1 inch (0-025 m.) thinner than at the Maidstone By-Pass. Part phosphatised fossils occur at the base of 5 (viii) and the species of Euhoplites indicate the nitidus Subzone, although the commonest ammonite is Dimorphoplites biplicatus (Mantell). Crushed Anahoplites planus occur in the top few inches, and there are a few uncrushed Euhoplites truncatus in the uppermost inch. 20 MIDDLE ALBIAN STRATIGRAPHY Whether the daviesi Subzone is represented at this height is uncertain. Sediments of daviesi Subzone age are 4 inches (0-101 m.) thick in the Maidstone By-Pass. The nodule bed Division 6 is of cristatum Subzone age, and it is interesting to note that there is a tendency for this bed to divide a little into two, a feature seen in Division D in Sections 2 and 4 of the Maidstone By-Pass (Owen 1960 ; 371). There is no question of there being two distinct nodule beds, but the feature is of interest in connection with the tectonic disturbance and associated erosion of the upper surface of the Lower Gault in cristatum Subzone times (p. 72). — Div. Lithology 2 Ins M. 6 Brownlsh phosphatic nodules tending to divide into two concentrationg 2 4-9 3 all in shelly medium-grey burrowed clay. 2 (vill) Mid-grey shelly clay with fawn patches- some extensively 3 | burrowed; scattered phosphatic nodules and part phosphatised BS 6 fossils at base, tc Wii) Highly burrowed light fawn-grey clay, shelly and with lenticles 1 of maristone at the base. 5 3 2-5 vi Mid-grey burrowed shelly clay. ey lI ~ 2 = Vv eam of scattered phosphatic nodules. Sea | iv. G mid-grey clay. os is i) Buffish phosphatic nodules in mid-grey clay. c 1 o e 8 (li) Shelly mid grey clay with lighter patches. E (i) Brown phosphatic nodules, mainly casts of fossils in shelly clay~ : 1-1 ‘o 3 i 4 Lightish fawn grey clay, shelly, becoming darker below and burrowed] © S « » a2 J “” 0 Fic. 7. Section in Lower Gault at southern side of the Associated Portland Cement Manufacturers’ Holborough clay pit, 880 yds SE. of Paddlesworth, Snodland, Kent (TQ 69156165). (b) Trottiscliffe The sequence exposed in the Rugby Portland Cement Co’s Ford Place Clay pit extends from the middle of the Folkestone Beds up to the varicosum Subzone of the Upper Gault. The Middle Albian sediments are shown graphically in text-fig. 8. Casey (1959) has given a brief account of the whole section, and a detailed account of the Gault-Lower Greensand junction beds (1961a ; 545). The upper part of the junction beds and the Gault have been described by Milbourne (1963) but his account is inaccurate both in lithological detail and in its subzonal classification. The writer has described the sequence in the spathi Subzone (1963a ; 38), but in view of Mil- bourne’s account of this section it is necessary to redescribe the sequence in the Lower Gault (text-fig. 8). Bed 9 of Casey (1961a ; 545) was stated to have a thickness of 3 feet (0-914 m.) and by Milbourne (1963 ; 58) as 5 feet (1-524 m.) : it is capable of subdivision (text-fig. 8). Bed 9 (ii) has yielded pyritic Hoplites (H.) spp. and Beudanticeras sp. and I follow Milbourne in classifying this horizon with the lyelli Subzone. Whether the eodentatus IN THE ANGLO-PARIS BASIN Div. Lithology [6 | Dense seam of phosphatic nodules and fossils in shelly grey clay. | (vl) Dark grey shelly clay with partly phosphatised and partly pyritised fossils. i (v) Mottled Bed. Light fawn grey clay with numerous burrows of dark grey clay. A shell seam with scattered phosphatic nodules marks the base, Scattered |_smal! phosphatic nodules occur at top. —— 5 (iv) Dark grey shelly clay. (iii) Shell seam with scattered smal! phosphatic nodules, (ii) Dark grey shelly clay, a little burrowed, with a few scattered small phosphatic nodules and some partly phosphatised fossils, (i) Bed of large Irregular phosphatic nodules and occasional part-phosphatise: n in dark grey clay. Fawn grey clay with shell seams and partly phosphatised fossils more A ferruginous and marly at the base which is marked by lenticular developments of ferruginous maristone. ‘i uN v nitidus cristatum meandrinus subdelarue/s niobe 10 or into Division 4, — (v)Irregular line of phosphatic nodules in dark grey clay. (iv)Dark grey shelly clay. (vi)Lighter grey clay than below, and more marly, passing in the top few inches (iii) Seam of scattered phosphatised ammonite body chambers, (ii) Darkish grey clay becoming increasingly shelly upwards, and lighter in colour. (i) Dark gritty grey clay with seams of whitish phosphate incipiently odular, Seam of black phosphatic nodules and mainly fragmentary casts o and other fossils in gritty dark grey clay. Gii)Dark grey gritty clay with numerous crushed fossils f ammonited. ) Dark grey gritty clay. (ili) Highly glauconitic green loam with scattered septarian phosphatic nodules. (ii) Highly glauconitic dark grey-green clay with a few pyritic ammonites. (i) Highly glauconitic dark grey-green loam with patches of grey clay septarian phosphatic nodules occur at 2and10 inches above the base, puzosianus Subzone sediments 1 (ii) Bed of pale soft phosphatic nodules and partly phosphatised Hoplites (H.) LG: ill-graded and pebbly in basal 6 inches. Thin seams of scattered spherical intermedius spathi lyelli Peodentatus 10 3 Se Me Oe es i e ry alla . 2 ° . . rites 10— =| 8-4 34 o— 21 Fic. 8. Section in Lower Gault at the Rugby Portland Cement Co. Ltd’s Ford Road clay pit, 450 yds N. of Ford Place House, and c. 1100 yds SSW. of Trottiscliffe on W. side of Ford Road, Trottiscliffe, Kent (TQ 63605910). 22 MIDDLE ALBIAN STRATIGRAPHY Subzone is represented in g (i), or whether 9g (ili) is of lyelli Subzone age, in the absence of fossils cannot be determined at present. The Lower Gault can be divided into six broad lithological divisions corresponding to those recognised by the author in the Sevenoaks area (1958 ; 152 and text-figs. 3, and 9g herein), and the correlation of these with Paddlesworth and the four divisions seen in the Maidstone By-Pass is shown in text-fig. 3. Division 1 (i) has not yielded fossils, but 1 (ii) to the top of 3 (i) are classified with the spathi Subzone. Division 1 (ii—iii) contain the same species of Hoplites (H.) that occur in the dentatus nodule bed at Folkestone. Division 2 is the ‘ upper dentatus-spathi nodule bed’ and contains the same ammonites that were recorded by the writer from bed 4 in the Lower Gault of the Buckland Sand & Silica Co. pit (Owen 1958 ; 151). No ammonites have been obtained from Division 3 (i), but at the base of 3 (ii) crushed Anahoplites intermedius and A. praecox appear in the succession, marking the base of the intermedius Subzone sediments, and range up through the remainder of Division 3. The coarse development of A. praecox known to occur in Bed II (iii) at Folkestone is found in the condensed bed 3 (iii), and Euhoplites price: ranges through 3 (iv) to the base of Division 4 (Milbourne 1963 table 1). The lower 4 feet 2 inches (1-321 m.) of Division 4 contains crushed examples of Dimorphoplites niobe, and these sediments are classified with the nzobe Subzone. As Milbourne has demonstrated, Mojstsovicsia subdelaruer and its contemporaries range throughout the remainder of Division 4. The meandrinus Subzone is represented within the sequence from Division 5 (i) to the top of 5 (v). The clays of 5 (1) to 5 (iv) contain the same fauna as Bed IV (iii) and the basal 2 inches (0-151 m.) of Bed V at Folkestone (Owen 1958 ; 157). However, 5 (v) was probably deposited at Trottiscliffe during a minor phase of non-deposition at Folkestone. The marked change in the ventral aspect of species of Ewhoplites which occurs suddenly 2 inches (0-051 m.) above the base of Bed V at Folkestone is not so abrupt at Trottiscliffe. In Division 5 (v) the peripheral aspect is transitional from the sulcate to the channelled state. Nonetheless, the characteristic species are more closely allied to the meandrinus Subzone rather than the nitidus Subzone. Division 5 (vi) contains a typical nitidus Subzone fauna but at the top, immediately beneath the cristatum nodule bed (Division 6), there are to be found the occasional part-phosphatised examples of Anahoplites daviest. Division 6 contains numerous usually fragmentary fossils in a matrix containing crushed or partly phosphatised fossils of cristatum Subzone age. There are well preserved phosphatised ammonites with the shell which are of daviesi or nitidus Subzone age which have just been caught up into the phosphatic debris of the nodule bed from the clays beneath. Nonetheless, the clay sediment of Division 6 is of cvistatum Subzone age. The phosphatic debris contains ammonites indicating the daviest Subzone, but essentially the cristatum Subzone. At Trottiscliffe, therefore, as at Paddlesworth at least in part, we see an expansion of the sequence found at the Maidstone By-Pass, but virtually all sediments of daviest Subzone age have been removed by the cvistatum Subzone transgression. This expansion of the sequence reaches its known maximum in this area at the Sevenoaks Brick Works Ltd’s pit at Otford. IN THE ANGLO-PARIS BASIN 23 Part of Division 5 and Division 6 were exposed during the excavation of the reservoir for the Mid Kent Water Board some 600 yds ENE. of the centre of the Ford Place Clay pit (TQ 64055920). The lower part of the Gault was also exposed in the now long-abandoned Pascall’s pit at Wrotham (TQ 62155780) about 2100 yds SW. of the Ford Place Clay pit and was described very briefly by H. J. W. Brown (1924 ; 79, 81). Nothing can be concluded from his account, but it is unlikely that the sequence has changed much from that at Trottiscliffe. (iv) SEVENOAKS AREA This area has been an important centre for the manufacture of bricks and tiles for overacentury. Pits have been opened near Kemsing Station (H.J.W. Brown 1924 ; 80), Greatness Lane, Otford (Austin Browne 1949 : Khan 1952 : Casey 1954a : Milbourne 1956, 1962, 1963 : Owen 1958, 1963a, b), St. John’s, Sevenoaks (Jukes- Browne 1900 : H. J. W. Brown 1924), Dunton Green (C. W. Wright 1947 : Khan 1952 : Casey 1954a : Owen 1958) and Chevening (Lobley 1880). These sections, with the exception of the last, together with borehole evidence has given a very good picture of the Lower Gault in this area. Brown (1924 ; 80) records the occurrence of the nodule bed (Division 6) at the top of the Lower Gault just N. of the railway line at Kemsing Station, but there is no other information available about the succession between Wrotham and Otford, a distance of 64 miles. Today, the only section available is that exposed in the Sevenoaks Brick Works Ltd., pit at Otford. (a) Sevenoaks Brick Works Ltd., Greatness The sequence in the Lower Gault at the Sevenoaks Brick Works Ltd pit at Great- ness Lane, Otford, is shown in text-fig. 9. It was first described by Khan who dis- cussed the foraminiferal sequence (1952), then in part by Casey (1954a) when describing the distribution of Falciferella. Milbourne has described the succession (1956, 1962) but his reading of it was questioned by the writer (1958, 1963a). The six broad lithological divisions seen at Ford Place reach their maximum development here (text-figs. 3 & 9). A combination of evidence provided by several boreholes together with surface mapping shows that the Gault-Lower Greensand Junction beds are over 13 feet 6 inches (4-11 m.) thick at Greatness. Division 1 (i) apparently is the transitional bed linking the Junction beds with the Gault. The writer reported (1963a ; 39) that the clays of i (ii) to (iv) probably represent the upper part of the benettianus (i.e. Lyellt) Subzone, and so the bulk of the Subzone is probably present in I (i) and, together with the eodentatus Subzone, in the sediments below. The species of Protanisoceras (P.) in I (ii-iv) include P. (P.) barrense (Buvignier) a characteristic lyelli Subzone am- monite. In comparison with Ford Place, it can be seen that clay sedimentation commenced earlier at Greatness. The spathi Subzone is represented by Divisions I (v—vi), 2, and 3 (i-ii). Division 2 is the ‘ Upper dentatus-spati nodule bed ’ as at Ford Place, and so, the sfathi sediments of Division 1 are slightly thicker at Great- 24 MIDDLE ALBIAN STRATIGRAPHY Olv. Lithology Dense band of phosphatic nodules containing semi-derived and indigenous fossils ng shelly clay (‘lautus Zone nodule bed’). $ | (x) Mo db gre awnish clay with some phosphatic nodules and ammonites. $nitiaus Line of partly phosphatised ammonites. = : | (vil) Blue-grey and fownish mottled clay with yellow ochreous balls after pyritic fossifs and occasional part-phosphatised fossils. (Wi) Seam of scattered part-phosphatised ammonites. | | | (v) Mottled blue-grey fawnish clay with yellow ochreous balls afterpyrite, and | | | | | | | ristatum 5 scattered phosphatic nodules (lv) Seam of dark-brown phosphatic nodules in clay of Stil). Bee I (ill) Mottled blue-grey and fawnish clay. (ii) Persistant seam of scattered part-phosphatised ammonites. » meandrinus (1) Mottled blue-gqrey and fawnish clay becoming more fawn-grey towards the base which Is marked by small lenticular developments of highly ferruginous 2 9 marly clay. Impersistant shell seams occur throughout, = = “ aie | > (ill) Dark slightly brownish-grey clay. = 1 9 i] ° = = ——— Pe Ce i 1 (ii) Seam of scattered dark brown phosphatic nodules, E Fa = : v a 2 > ” 3 104 (i)Broad banded clays; alternating dark-grey clay and lighter grey marly, with lanticular developments ot ferruginous maristone especially inthe 6 2 lower band which varies between 10 and 18 inches in thickness. SSS niobe I ba are (vi)Dark grey clay with scattered chocolate coloured phosphatic nodules witha Aine Oe RUE sole 9 zinch thick line of them at the base. stele -o ie, i alate AY, pe e@aesecse o (v) Dark grey shelly clay. 2 Bi a— — = 1- (iv) Seam of shells with small buff phosphatic nodules and phosphatised ammonite Sete SSS 2 body chambers. ohh cy 7] > > | . ] iS & . 3 (iii) Dark grey shelly clay with lighter grey bands alternating: scattered buft = 12 ° c phosphatic nodules. ~ os | 1 < = 4—s (il) Greenish glauconitic clay, = 9 (i) Dark grey shelly clay, - 2 Lo} 2 Dense seam of black phosphatic nodules and casts of ammonites, often with the = shell, in dark grey shelly clay. ° eae “G 1-2 mae oe ba’ (vi)Shelly dark grey clay with part phospatised fossils in a shell seam 10 inches ~ 3 ” from the base, 1 5 {v) Shelly seam with phosphatic nodules and fossils, Vv eRe dees 1 = eee of— (tv) Dark grey shelly clay, * — 9 | (ill) Shel! seam with phosphatic nodules, ue cine meer (S ; 1 " (li) Dark grey shelly clay. 2 1 . (i) Dork grey sparsely fossiliferous clay becoming more glauconitic downwards ~ with patches of glauconite in the lowest part exposed, = 5 9 1 | | | | | {e) Fic. 9. Lower Gault section at the Sevenoaks Brick Works Ltd’s pit, 1300 yds NNE. of Bat & Ball railway station, 150 yds S. of the Otford-Kemsing railway line, and 150 yds W. of Greatness Lane, Otford, Kent (TQ 53605780). IN THE ANGLO-PARIS BASIN 25 ness. Division 3 at both localities is closely comparable in thickness and character except at its base, where 3 (i) at Ford Place has become finer in character and shelly by Greatness and is represented in 3 (i-1). Ammonites that occur in 3 (i) at Great- ness consist almost exclusively of species of Hoplites (H.), the fauna being identical to that of the indigenous element of Division 2 itself which contains rarities such as Oxytropidoceras but no examples of Anahoplites were found by the writer. At Great- ness, 3 (ii) contains a few large Inoceramus concentricus but no ammonites. At the base of 3 (ii), Anahoplites intermedius and A. praecox appear in the sequence and this is taken by the author to mark the base of the intermedius Subzone. They range up to the top of Division 3 as at Ford Place. The thin seam of ‘ solid’ phos- phatised ammonite body chamber fragments containing the coarse form of A. praecox is also present at Greatness (3 iv), and above this Ewhoplites priced and its close relatives are characteristic as at Ford Place. Division 4 is thinner than at Ford Place, and only the basal 2 feet 2 inches (0-66 m.) can be classified with the niobe Subzone in contrast to the 4 feet 2 inches (1:27 m.) at Ford Place. At the level 2 feet 2 inches (0-66 m.) above the base of Division 4 at Greatness there is a thin bedding plane (bed 10 of Milbourne 1956 ; 236) which contains species of Mojsisovicsia including M. subdelarue: (Spath). This marks the base of the swbdelaruei Subzone which is here 8 feet 7 inches (2-616 m.) thick, and is, therefore, thicker than at Ford Place. M. remota (Spath) has been obtained from 4 (iii) ; and 5 (i) has yielded species of Dimorphoplites which indicate the swbdelarwei Subzone rather than the meandrinus Subzone although Mojsisovicsia has not yet been found init. It is important to note that lithologically the base of Division 5 at Ford Place does not correspond to the base of the same lithological Division at Greatness. The meandrinus Subzone commences with 5 (ii) which has yielded Euhoplites meandrinus Spath, E. aff. asbasia Spath, Dimorphoplites spp. and large partly crushed Anahoplites planus (Mantell). No ammonites were recovered from 5 (iii) but the nodules of 5 (iv) have yielded fragmentary abraded Dimorphoplites and Euhoplites. At Greatness 5 (ii) to (iv) can be correlated with 5 (i) at Ford Place. Division 5 (v) to (vi) at Greatness also contains a meandrinus Subzone ammonite fauna, but 5 (vii) did not yield ammon- ites to me and probably represents 5 (v) at Ford Place which contains an ammonite fauna which shows some affinity with the mztidus Subzone above. The mtidus Subzone without doubt commences at the base of 5 (viii) at Greatness and includes 5 (ix). Together they have yielded a typical mitidus Subzone fauna and measure 4 inches (0-102 m.) in thickness in comparison with the 1 foot 4 inches (0-406 m.) of 5 (vi) at Ford Place. Division 6, the ‘lautuws Zone nodule bed’, as the author demonstrated in 1958 contains a fauna including elements of the mitzdus and daviest Subzones as well as of cristatwm Subzone age. Here, as at Ford Place, the age of the clay in which the phosphatic debris is embedded is of cvistatum Subzone age. It is worth revising here the stratigraphical positions of the samples studied by Khan (1952) from the Sevenoaks Brick Works. Sample Sr 5 ft 6 ins down from the top of Division 3 ; intermedius Subzone as Khan recorded. Sample S2 6 ins down from the top of Division 3 ; intermedius Subzone as Khan recorded. 26 MIDDLE ALBIAN STRATIGRAPHY Sample $3 1 ft 6 ins below the top of Division 4 ; subdelarueit Subzone not niobe as recorded. Sample $4 _ 6 ft below the top of Division 5 ; subdelaruet Subzone not niobe as recorded. Sample $5 4 ft below the top of Division 5 ; subdelaruet Subzone. Sample S6 2 ft below the top of Division 5 ; meandrinus Subzone. Sample $7 2 ins below the top of Division 5 ; nitidus Subzone not subdelaruei Subzone as recorded. Sample S8 ‘ Jautus-Zone nodule bed’ Division 6 ; cristatum Subzone. (b) St. John’s Brickyard The brickpit owned by Durtnell and known in the literature as St. John’s Brick- yard, or the ‘Bat & Ball’ pit, is now overgrown. It was situated about 900 yards NNW. of the Bat & Ball railway station, 100 yds W. of Otford Road, Otford (TO 52805755), and goo yds towards the WSW. of the Greatness pit. The section was first described by Hill (tn Jukes-Browne 1900 ; 85) and additional information was given by H. J. W. Browne (1924) and by Spath (e.g. 1925 ; pl. XII, fig. 4). It showed a sequence (text-fig. 3) intermediate in thickness between that of the Great- ness pit and the Dunton Green section described next. (c) Dunton Green The Dunton Green Brick, Tile and Pottery Works Ltd pit was situated about 1650 yds WSW. from the St. John’s Brickyards. The section is now obliterated. It was first described in detail surprisingly late in its history by C. W. Wright (1947 ; 315-318) although it had been mentioned in the literature as early as 1880 (Lobley 1880). Spath recorded ammonites from it (1923-43) and Khan (1952) and I (1958) have referred to it briefly. Unfortunately, I saw only the sequence up to the basal part of Division 4, and the dotted portion in text-fig. 10 is taken from the account by Wright. Text-fig. 3 shows the extent to which the sequence is attenuated in comparison with that at Greatness to the ENE. and the Brasted borehole to the WSW. (not ESE. as given in Casey 1954 ; 266) discussed below. The exposed portion of Division 1 at Dunton Green was seen to be identical to the corresponding portion of Division 1 at Greatness. Division 2 contains the same fauna as at Greatness but the phosphatised material is devoid of the shell. Division 3 (i) contains ‘solid’ pyritised Hoplites (H.) with the nacreous shell, including H. (H.) dentatus densicostata Spath and H. (H.) escragnollensis Spath. This bed corresponds to 3 (i) at Greatness. The basal 2 feet 3 inches (0-686 m.) of 3 (ii) at Dunton Green consists of a glauconitic clay, immediately above which Anahoplites intermedius appears in the sequence and ranges up through the remainder of the Division. Although the sequence is much more condensed, the thin bed of phosphatised body IN THE ANGLO-PARIS BASIN 27 — = Div. Lithology Ft Ins M. [eT Bade doth town bresphetle nadulen OIIIILILII“AS eye 4 ! 1 ! l 1 I | ! ! | i. i ] | | “ 3 1 5 , | = ; a Lightish grey clay, slightly mottled, darkening below. 1s nes sy Wright 1947;318] | | 0] \ I 1s 6 ! I 1 c 1 1 1 i} ! | ! 1 ' J ! 1 ' ! | ! | 5 Lightish-somewhat fawn-grey clay. seen to fe) (lv) Dark-grey clay with small dark-brown phosphatic nodules, ° (iil) Shell seam with phosphatised ammonite body chambers. { 4 “” = vv +7 iS = 3 = (ii) Dark grey clay with crushed fossils andscattered small phosphatic nodules passing down at the base into 10 6 glauconitic gritty clay. 2 1 (i) Dark grey clay, shelly with some pyritised ammonites. ~ 6 Dense seam of black phosphatic fragments of ammonites etc. = 12 Dark grey clay with crushed fossils chiefly ammonites. 6 ce) Fic. 10. Section in Lower Gault at the Dunton Green Brick, Tile & Pottery Works Ltd’s pit, c. 550 yds S. of Dunton Green railway station on E. side of railway line, Longford, Dunton Green, Kent (TQ 515570). The dotted portion is completed from the account by Wright (1947). 28 MIDDLE ALBIAN STRATIGRAPHY chambers of ammonites 3 (iii) occurs, and may be correlated with 3 (iv) at Greatness. 3 (ili) at Dunton Green has yielded the coarse form of A. praecox figured by Spath (1925 ; 132, text-fig. 35e) according to its preservation. Only a foot of Division 4 was seen clear by the writer, and for the remainder of the sequence Wright’s account is available. (d) Brasted The Metropolitan Water Board well at Brasted has been described by Casey (1954a ; 266 : 1961a ; 544-5) and is displayed in text-fig. 11. Its relationship to the sections at Dunton Green and Squerryes is shown in text-fig. 3. The sequence in the higher part of the well is similar to that of Dunton Green and Greatness. Un- fortunately, the top of the Lower Gault bisects the ground surface further to the north of the site of the well, and the boring commenced at an unknown depth below the base of the Upper Gault. At a depth of 12 feet 6 inches (3:81 m.) the reddish burrowed marl suggests a correlation with the base of 5 (i) at Greatness. The only two ammonites preserved in the collection of the Institute of Geological Sciences (GSM) are Ca 339, Ewhoplites sp. from a depth of about 8 feet (2-438 m.), of either swbdelarue: or meandrinus Sub- zone age, in the preservation typical of the lower part of Division 5 at Greatness. The other, Ca 340 from a depth of 10 feet (3-048 m.), is of no diagnostic value. Together they neither confirm nor deny a subdelaruei Subzone age. The dividing line between Divisions 4 and 3 occurs between a depth of about 22 feet and 25 feet (6-706—7-62 m.) where the lithological change from fawn-grey clay to mid-grey clay occurs. The equivalent of 3 (iii) at Dunton Green occurs at a depth of 29 feet (8-839 m.) and yielded Anahoplites praecox (GSM Ca 364-6) and Hoplites (H.) sp. (GSM Ca 367). At a height of 1 foot 6 inches (0-457 m.) above Division 2 a phosphatised fragment of a coarsely ribbed Anahoplites with the nacreous shell preserved was recovered. Division 2, the ‘ upper dentatus-spathi nodule bed ’ was struck at a depth of 38 feet 6 inches (9:296 m.). Below this level the sequence departs markedly from that of Dunton Green and Greatness. The 20 feet 6 inches (6-248 m.) of mid-grey clay below Division 2 contains Hoplites (H.) spp. throughout. No definite indication of the lyelli Subzone is seen, but a boring encompasses only a very small lateral area and the possibility that part of this succession is of lyelli Subzone age should not be dis- counted. There was also no evidence of the eodentatus Subzone although this may be present below 59 feet (17-983 m.) depth. (v) BRASTED TO BUCKLAND (a) Westerham The northern face of the Squerryes Estate Sand pit situated 24 miles SW. of the Brasted Well was cut back in 1964 and provided the section given in text-fig.12. The sequence of well-marked lithological divisions seen in the lower part of the Lower Gault in the Sevenoaks area, already indistinct at Brasted, becomes even less dis- tinct at Squerryes. Here, two clear-cut divisions are immediately apparent and IN THE ANGLO-PARIS BASIN Olv. Lithology Light grey weathered clay marked at the base by burrowed reddish marl, Vs c le Ie le ,& 1 le a LS le Fawn grey clay with phosphatic nodules. | 1 | | / (ill) Mid grey shelly clay. “ = v ev (li) Shell seam with phosphatised ammonite body chambers. E £ = (1)Mid grey shelly clay. yN Ur te Blackish phosphatic nodules and fragmentary fossils with the shell ie Qa ” (v)Mid grey shelly clay. (iv)Phosphatic fragments of fossils with the shell. (iii)Mid grey shelly clay with part-phosphatised, part-pyritised fossils. (ii) Phosphatic fragments of fossils with the shel! in mid-grey clay. (i) Grey shelly clay. Black sandy clay with phosphatic nodules andiron pyrites. Remainder of Bed 8 of Casey 1961a;545. Ft — i — 22 at 4% see a — 29 Ins M. = = = Fic. 11. Vertical section of Middle Albian sediments in the Metropolitan Water Board well, 1000 feet NE. of St. Martins Church, to the E. of Station Road Brasted, Kent (TQ 47095574). 30 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology (vil) Mottled blue-grey-fawn clay with crushed /Inoceramus concentricus and Hoplites(H.) spp. with the shell. Seen to (vii) Blackish phosphatic nodules mainly casts of Hoplites (H.)with portions of shells preserved, in shelly mottled clay. (vl) Clay as in 2 Wiii) with partly phosphatised Hoplites (H.) spathi (v) Clay asin 2 Wiii) but much less fossiliferous. (iv) Shelly grey-blue-fawn clay with part-phosphatised part pyritised Hoplites (H.) iii) /.concentricus shell seam with part-phosphatised fossils | (il) 2’ mottled Dlue-grey clay with crushed fossils i) Dense seam of small phosphatic nodules and phosphatised fosstts Mottled blue-grey-fawn clay with lenticles of ferruginous marl. Clay as in 1(v) but without phosphatic nodules, and with pockets of glauconitic quartz sand, and ferruginous lenticles. Crushed part-phosphatised Hoplites (H.)occur without the shell. (iii) Darker grey clay with ferruginous lenticles with indigenous part—phosphatised Hoplites (H,). (ii) Lighter grey clay with many ferruginous lenticles. Small phosphatic pieces with Hoplites (H.). tyelli (i) Dark grey shaly mottled clay with reddish ferruginous lenticles. Dark grey gritty clay. eign. pyritic dark grey clay with greyish septarian phosphatic no jes and .part-phosphatised fossils wit PY rite replaced shells; s| c Dn oO Cg no © a 0 en Dark grey pyritic clay, gritty, and weathering ferruginous, Dark grey highly pyritic clay with septarian phosphatic nodules weathering ferruginous. Dark gritty grey clay with scattered septarian phosphatic nodules. Seam of large spherical blackish phosphatic nodules in glauconitic lob Black gritty blocky weathering clay with glauconite, When weathered clay partings are coated with pyrite decompos- ition products, eodentatus _ = = ale ele Bed 12 of Casey 19610;543 puzosianus Subzone Fic. 12. Middle Albian sediments at the Squerryes Estates Sand Pits’ pit, c. 150 yds N. of Covers Farm, Westerham, Kent (TQ 43305395). IN THE ANGLO-PARIS BASIN 31 their correlation is shown in text-fig. 3. The sequence is, however, thinner than at Brasted. The g feet 2 inches (2-794 m.) of Division 2, excluding bed (i), contains a typical spatht Subzone fauna, the ‘ upper dentatus-spathi nodule bed’ being represented in 2 (vii). Bed (i) is the highest level in which Protanisoceras (P.) moreanum (Buvignier) occurs, and this is taken to mark the top of the /yelli Subzone sediments. The under- lying 11 feet (3-353 m.) of Division 1 represents the uppermost part of the lyelli Subzone as developed at Horton Hall, Sussex (p. 35). However, the typical develop- ment of this Subzone occurs within beds 13-15 of the Gault-Lower Greensand Junction. Bed 15 has yielded the following ammonites: Protanmisoceras (P.) moreanum (Buvignier), Beudanticeras laevigatum (J. de C. Sowerby), B. sanctaecrucis (Bonarelli), B. albense Breistroffer, Hoplites (H.) dentatus (J. Sowerby), H. (H.) bullatus Spath, H. (H.) baylet Spath, Lyelliceras lyelli (d’Or- bigny), Brancoceras versicostatum (Michelin non d’Orbigny, nec Douvillé), ‘ Oxytropi- doceras ’ cf. evansi (Spath). Bed 13 has yielded Beudanticeras laevigatum, Hoplites (H.) spp., ? Otohoplites sp. ind., Lyelliceras sp. Beds 10-12 contain Hoplites (Isohoplites) spp., including H. (J.) eodentatus (Casey 1961a ; 543). (b) Tandridge The Coney Hill Sand-pit, Barrow Green (TQ 37755250), situated about 3} miles WSW. from Squerryes, has already been described by the author (1963a ; 39). It is apparent that the sequence has become thinner (text-fig. 3). Between Tandridge and Buckland, a distance of 9 miles, there is no information concerning the sequence at the outcrop. (c) Buckland The Buckland Sand & Silica Co’s pit at Buckland (TQ 231512) was described by the author in 1958 (1958 ; 149-152), however, a certain amount of revision is now necessary. The sequence (text-fig. 13) is not unlike that of Ford Place, a fact already recognised in the Gault-Lower Greensand Junction Beds by Casey (1961a ; 552). Whether the eodentatus and lyelli Subzones are present in the upper part of the Gault-Lower Greensand Junction as at Ford Place is at present unknown (p. 20). The spathi Subzone is represented within beds 2-6. Bed 2, tentatively classified with the benettianus Subzone in 1958, was later included in the spathi Subzone (Owen 1963a ; 47-48). It contains the same ammonites as Division I (ii) at Ford Place. Bed 3 is the obvious correlative of 1 (iii), and Bed 4 is the equivalent of Division 2, the ‘ upper dentatus-spathi nodule bed’. Bed 4 has yielded the best preserved fauna yet known from this horizon, and the effect of strong erosive currents on the sea- bottom is demonstrated by the effaced nature of the upper surface of the nodules. Beds 5-11 probably represent Division 3 at Ford Place but the character of the clay is very different. In general the sediments are gritty clays with intercalated beds of ferruginous marlstone, and the fossils have shells replaced by pyrite. Beds 5 and 6 32 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology subdelaruei Mottled brown and blue-grey clay with selenite. A seam of crushed 2 {e) bivalves occurs at the base with poorly preserved part-phosphatised | ammonites. 8 Light-grey weathered clay with much selenite. S 3 3 ° c 7- 11. | Very dark brown clay. 4 ie) 64 r_ “ = v vo 10 | Dark blue-black blocky clay with yellowish patches mainly on g 3 fe) partings. © = Highly ferruginous yellowclay with stony lenticles of reddish marlst— = 7 5 2h one containing disc-shaped pebbles of micaceous maristone, 4 (e) 8 Dark grey clay with pyritised and partly-phosphatised ammonites but usually crushed flat, 4 "GM ID NEGLI LD) — 4 Impersistent but well developed lenticles of hard ferruginous marlstone with lateral interstitial gritty clay-marl. PL | fo) 6 Hard brownish marly clay with marly seams passing down into the bed below. A 2 5 Dark grey slightly mottled clay. = Oo [ 3 Greyish-white to black phosphatic nodules, brownish when a 4) weathered, mainly ammonite casts with abraded upper surfaces ™4 3 Dark grey clay with pockets of glauconite, some oxidised. Phosphatic nodules occur scattered at about the middle of the 34 bed, Scattered subangular phosphatic nodules in gritty glauconiticclay. | 2 2 Gritty glauconitic clay with patches of glauconite sand. ° 6 = (@) Gault—Lower Greensand junction beds Fic. 13. Section of Lower Gault in the Buckland Sand & Silica Co’s sandpit extending from a point 2100 yds WNW. of Reigate railway station to a position c. 250 yds SW. of Dowdes Farm, and 50 yds S. and roughly parallel to the Dorking-Redhill railway line, Buckland, Surrey (TQ 232512). M Ft HASSOCKS HORTON HALL STORRINGTON PITSHAM NYEWCOD SELBORNE WRECCLESHAM SHERE BUCKLAND TANDRIDGE 140 oS ubdelarvei{_ 13 niobe 12 ee a0 M1 130 ile) fee 9 8 intermedius a7 ? ? 2 ? 6 7120 L, 354 — >] —— 4 6 9 3 P2Zyeee| 5 — a 4 [110 | 3 spothi 7 > 30400 = SS NSN 0 ON 6 . S = 4 }90 — 3 ? 2) ————e ? 255 L Broad eodentatus 60 ? ? 770 205 +60 15450 Subzonal correlation lines —_- — — ——Lithological correlation lines L40 104 30 20 5: 10 Fic. 14. Correlation of sections in Surrey, Hampshire, and Sussex, at the outcrop. ar } 2 Sacre. 0 - £ : 7 - IN THE ANGLO-PARIS BASIN 33 are classified with the spathi Subzone, Beds 7-11 with the intermedius Subzone. The siltier nature of the sediments of the zmtermedius Subzone heralds the sequence seen further west at such localities as Winchester (p.69), Didcot (p.63), and Devizes (p.60). The mobe Subzone is probably present in the top of these sediments and possibly in the light grey clay of Bed 12 which can be correlated with the base of Division 4 at Ford Place. A re-examination of the ammonites from Bed 13 indicates that it should be classified with the subdelaruet Subzone as the writer considered possible in 1958. The presence of higher Middle Albian subzones in the sequence is at present un- certain. Gossling (1929 ; 251) reported, from Spath’s determinations of the am- monites found in the Merstham trench, that here the Upper Gault rests directly upon the dentatus Zone. However, Gossling did not give a detailed account of the succes- sion and, moreover, the trench was only 4 feet (1-219 m.) deep. In the Buckland Sand & Silica Co. pit large distorted blocks of pale-grey clay were seen in the super- ficial deposits. These blocks contain orbignyi Subzone fossils and the bed from which they were torn cannot be far to the northward. However, in the foundations of Wray Common County Primary School at the N. end of Kendal Close, Reigate (TQ 26975092), the ‘ lautus Zone nodule bed’ was located. The fauna obtained indicated that its character was closely comparable to that of Division 6 in the Sevenoaks area. (vi) BUCKLAND TO UPPER BEEDING (text-fig. 14) There is very little information available at the outcrop between Buckland and Shere, a distance of 104 miles, except that given by Dines & Edmunds (1933). The sections exposed during the cutting of the Shere By-Pass road have been described by the writer (Owen 1963a). There is very little doubt that the outcrop here is affected by a strike fault with a substantial northerly throw as Kirkaldy concluded (1958 ; 18). The structure illustrated by the author (1963a ; 41, text-fig. 1), the greatly attenuated width of the outcrop, the far greater thickness of the Gault in the West Clandon Waterworks boring, and the sequence at Albury (Edmunds im Dines & Edmunds 1929 ; 41-2) all support the presence of such a fault. The true degree of representation in the Lower Gault in this area is, therefore, uncertain, and will not be determinable until a cored borehole is drilled to the north of the disturbed ground. The notable feature in the lower part of the Lower Gault between Shere and Shalford is the development of the eodentatus and lyelli Subzones (Owen 19638, Wright & Wright 1948). Whether this development continues west to Whiteacre Copse on the Guildford-Godalming By-Pass road is unknown (Lea 1932 ; 320-1 ; Owen 1963a ; 50). There is a similar dearth of information further west. However in the Institute of Geological Sciences there is a small suite of specimens from the Gault exposed in a gravel pit off the Farnham to Runfold road at about 1 mile ENE. of Farnham and immediately W. of the railway bridge (SU 85854755) GSM. He 2337-45, which indicates the presence of Jawtus Zone sediments in this area. The sections at Wrecclesham, Selborne, and Nyewood, have all been described by the writer (Owen 1963a). Text-fig. 14 shows that the sequence in the spathi Subzone Cc 34 MIDDLE ALBIAN STRATIGRAPHY expands south of Wrecclesham to reach its greatest known thickness in this area at Selborne. It then thins southwards towards Nyewood, and between this locality and Storrington the Gault rests directly upon the oxidised indurated ‘ iron grit’ at the eroded top of the Folkestone Beds. How much more of the Middle Albian is represented in the higher beds of the Gault is uncertain. I expressed the qualified opinion (1963a ; 51) that at Selborne it appeared that the cristatum-orbignyi Subzone transgressions had cut down to the spathi Subzone, a view disputed by Milbourne (in Hancock 1965 ; 250). Osborne White (1910 ; 17) followed Jukes-Browne’s interpretation of the ‘ inter- ruptus ’ Zone (see p. 111). He records at Bradshott Hall (1910 ; 20) 2 feet (0-609 m.) of clay with phosphatised ‘ Hoplites interruptus’ separated by 3 feet (0-914 m.) of deposits from sediments containing Inoceramus sulcatus indicative of the lower part of the Upper Albian. Unfortunately, this material has not been traced. The lowest part of the intermedius Subzone with Anahoplites osmingtonensis nov. is present at the outcrop in the Petersfield area (e.g. BMNH, C 35482-3). Further information has been provided by borings carried out for the Gas Council by the British Petro- leum Co. in the Winchester area in the deeper part of the Wessex basin (p. 69). There, sediments of the intermedius Subzone are present above the spathi Subzone, and the orbignyi Subzone is also represented within the silty clay facies. Between Petersfield and Storrington only three sections are available, all in the spatht Subzone ; Nyewood, Pitsham, and Sullington (Owen 1963a). Recently, Mr. C. J. Wood of the Institute of Geological Sciences recognised in the Brydone Collection the material recorded by Jukes-Browne (1900 ; 112) from a well to the N. of Graffham village. The specimen recorded as Hamites punctatus ? is here referred to Protanisoceras (P.) barrense (Buvignier) and is preserved in lilac-grey silty clay, the shell originally having been replaced by pyrite. It is accompanied by Inoceramus concentricus in the same preservation. The ammonite indicates the lyelli Subzone. The specimen of Hamutes attenuatus is indeed of that species, but is preserved in weathered yellowish pale-grey tough silt. It is of either Jovicatus or possibly lautus Zone age. Osborne White (1924 ; 26) described a well section examined by Templeman situated on the W. side of the lane to Barns Farm, 300 yds S. of its junction with the Washington-Storrington A283 road (TQ 10501345). Below 10 feet (3-048 m.) of clay containing an Upper Gault fauna, about 40 feet (12-192 m.) of Lower Gault was proved including the cristatwm and the upper part of intermedius Subzones. Ina well bored at Wiston Hall between Washington and Steyning 176 feet (53-644 m.) of Gault was proved (Osborne White 1924 ; 25). It seems likely, therefore, that in this area the succession in the post spathi Subzone sediments is closely comparable to that described below exposed in the Horton Clay pit. (vii) UPPER BEEDING The Lower Gault section exposed in the British Portland Cement Manufacturers Ltd’s Horton Clay pit is shown in text-fig. 15, and its relationship to sections west and east is shown in text-fig.14. The pre-war workings were described by Osborne White IN THE ANGLO-PARIS BASIN 35 (1924 ; 27-8), and the current sections have been described in part by Milbourne (1961 ; 135-7), Casey (I961a ; 558), and Owen (1963a ; 46). It shows the thickest sequence yet known in the Lower Gault of England, and is undoubtedly the most important. The clays contain finely disseminated pyrite, and their silty nature allows the deep penetration of weathering agents ; this obscures the bedding for at least 12-14 feet (3-658-4:267 m.) from the surface, but fortunately there is a dip of 8°S. present. In the fresh condition, the clays are seen to be fairly uniform through- out, and the Divisions adopted here are based upon cycles of sedimentation. Each cycle commences with relatively rapid sedimentation and terminates with partly arrested deposition indicated by marly seams and cementstone nodules. Individual units display an alternation of dark-grey and more fawn-grey bands. That this is an original feature is occasionally shown by the fauna ; there being often a more diverse benthos in the fawn-grey bands. Casey has described the boreholes drilled over the area of the northern field situated to the E. of Horton Wood (1961a ; 558). The subsequent excavation of this field commenced in 1964 at the northern boundary, and the sequence is now being cut down dip. There is unfortunately a small gap in the observed sequence as shown in text-fig. 14, between this new field and the older workings. Eodentatus & basal lyella Subzones About 13 feet (3-962 m.) of glauconitic sandy clay and loam (rz (i) & (ii) ) classified with these Subzones occurs below the lowest level seen in the excavations (Casey rg6ra ; 558). lyella Subzone Divisions I (ii) to the top of 2 (vi) are classified with this Subzone. As this is the first time that such a faunal sequence has been described in England, it is discussed in detail. The top 3 feet 8 inches (1-117 m.) of I (ii) is seen in the excavations, but only the upper foot is fossiliferous and this has yielded Hoplites (H.) spp. and the ubiquitous Inoceramus concentricus, among other fossils. The shell seam that marks the base of 2 (i) has yielded the following :— Protanisoceras (Protanisoceras) nodonewm (Buvignier). P. (P.) barrense (Buvignier), P. (P.) alternotuberculatum (Leymerie), Beudanticeras laevigatum (J. de C. Sowerby), B. albense Breistroffer, Hoplites (H.) spp., Lyelliceras aff. lyell (d’Orbigny), Branco- cevas (Brancoceras) sp., Neohibolites minimus (Miller), I. concentricus Parkinson, Acila (Truncacila) bivirgata (J. de C. Sowerby), Natica sp. A comparable fauna occurs throughout the remainder of 2 (i). In 2 (ii) the benthonic element of the fauna increases in importance and one of the characteristic fossils is a solitary caryophyllid coral. The ammonites consist essentially of species of Hoplites (H.) and Protanisoceras (P. barrense & P.nodonewm) ; Lyelliceras is not common. The benthonic element is much reduced and the nekton to a lesser extent in 2 (iii). The ammonites include the following : H. (H.) dentatus (J. Sowerby), H. (H.) spp. common ; P. (P.) barrense, Lyelliceras Wells (d’Orbigny) the lowest definite occurrence of the typical form, Beudanticeras sp., accompanied by I. concentricus. "25Dq 24, Wosjy sayrurz 322)gG Jo yUBiay D YD aay pdyO2!pUl si pung 4aiybiy auO ‘a}0}s Pas24y}DaM DU! KjUO Uaes U2aq soy Bulysom Ajsayysou Dy) UL puD UDa|S KJjN) 32K JOU Ss! UOIS!AIpqns stuL "SI!SSO} p2s!youdsoyd ° J4od ulpjyuo> pud ayDUsa}}0 Spudg 42x46 AjyyBrys “swoas j{ays p2s2zyo2s YyIm AdI> Aj jaus snoa2021w Ajyybiys f£asB ys0g (1 ° Oe fo} “104 4BMO] JYX U! 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"S|'SSO) pastyOYydsoyud—jysod POUT Ee ei P2aAsasasd Ajjnjiynvaq spa *sao01d 1194US Y “Saz!uOWWD Ppat!youdsoyd—-yund absn; awos yyIm ADdI> Ajjaus Aasb-umo4y (A!) *Aoi> Aitaus Aovsb-umpy 0} Aasb-piw f2,1UOWWD pasi;DYydsoud-yso0d abso; awos yyImM Avdi> Ajjaus Aasb-umoy4 ul yno paysom fasDq 24} |Aoqgd s2ycdu! » WDas *suo'y042uU0> AjsDwW jy}Os UI “sajnpou 2!;0Yudsoud p3sd},}09s M2}; D PuDdD "sn 21s, ua2u02 SNwose20U/ PUD (‘H) SestidoH Paysns>d AuOW YyIM Adj2 Ajjaus Kas6 xjog (') “doy 4D OsjD-sj! sso} pati;0Yudsoud-yJ0d pud sajnpou 2u0);s;UaWa> Buruioyuo> as0q yD Woes |124ys OD YyIM Adia Aljays painojo> UMDY (!1) “S|ISSO} PastyDydsoyd Aj,s0d Ma) D YYIM AdI>D Ajjous Avsb ying (i “S|!SSO} PastyDydsoyud-jso0d awos PUD sUO!;a42U0D BUOISJU2W|TD YIM ADI> Ajlazus PBUNOJO> UMDY (At) Pasijoudsoyd ysDd joUuo!sD220 YyyImM AdI> Alloys AvsB-um_d); asow puod S|!ssop pdyusns> YIM "spuoqg JayiDp OM, Aq pa2yoindas Buraq spuog ysiumo) 2asy} 24, ‘ADj>2 A2u6 yuDp yo ys!Su0> spunq jsaybiy pun samo} auL *SayiuowwD spuog Avdj> Ajjays Aasb ysnp Buljyousayiy (1) 38 MIDDLE ALBIAN STRATIGRAPHY A much more diverse fauna appears in 2 (iv). A thin bedding plane 4 inches (0-I0or m.) above the base, sometimes washed out, has yielded one of the best pre- served ammonite faunas yet known from the lyelli Subzone. The fossils are part- phosphatised and part pyritised. Some ammonites are in a ‘ death rest’ position ; that is, they are vertically orientated resting on the venter. The amount of distortion permits the compaction ratio of the clay to be deduced. The fauna includes : P. (P.) nodoneum, P. (P.) barrense, Pseudhelicoceras argonnensis (Buvignier), P. sp., Beudanticeras laevigatum, B. albense Breistroffer, B. sanctaecrucis Bonarelli, Hoplites (H.) baylet Spath, Hoplites (H.) spp. Douvilleiceras sp. juv., Oxytropidoceras evansi (Spath), O. sp., Lyelliceras lyelli (d’Orbigny), L. gevreyi (Jacob), L. sp., Brancoceras senequiert (d’Orbigny), B. versicostatwm (Michelin non d’Orbigny nec Douville) B. spp., Inoceramus concentricus, Semisolarium moniliferum (Michelin). ‘ Auricula’ acuminata Deshayes. Hemuaster sp. This list shows a preponderance of lyelliceratid ammonites over the hoplitids which are greatly subordinate in actualnumbers. The fossils are mainly crushed flat in the remainder of 2 (iv) and (v) but there is no significant difference in the fauna. Large uncrushed or partly crushed fossils occur in 2 (vi) and include : P. (P.) barrense, Beudanticeras sanctaecrucis, H. (H.) benettianus (J. Sowerby), H. (H.) spp., Lyelliceras lyell, Brancoceras spp. Eutrephoceras sp. At this level Hoplites occurs in roughly equal numbers to the non-hoplitid genera combined. Some of the ammonites are also in a vertical ‘death rest’ position and these, like those in 2 (iv), have a common orientation indicating a current direction coming from what is now 210° Magnetic. spatht Subzone Divisions 3 and 4 are classified with this Subzone. There is a sharp change in the ammonite fauna at the base of Division 3, the ammonites consisting essentially of Hoplites (H.) spp. At the commencement of the spathi Subzone, deposition of sediments increased rapidly and the bulk of the remainder of the Lower Gault, although very fossiliferous, yields little but crushed material except at a few horizons. Sedimentation during the spatht Subzone was particularly thick. At least 56 feet 9 inches (19:812 m.) of clays have been observed and the gap in the sequence between the northern field and the main workings is probably only a few feet. Division 3 (i) contains numerous J. concentricus and crushed Hoplites (H.) the bulk of which possess dentatus-like ribbing : a few pyritic nuclei occur. Protanisoceras (P.) spp. have been obtained from Division 4 (i) but otherwise the heteromorph ammonites are almost exclusively species of Hamites. A beautifully-preserved fauna occurs in 3 (ii)-(iv) consisting mainly of ammonites and almost entirely of species of Hoplites (H.) identical to that of the well preserved element in the dentatus nodule bed at Folkestone (p. 13). Some specimens reach a diameter of 9 inches (0-228 m.). A loose block certainly from either 3 (ii) or (iv) contains an example of Mojsisovicsia delaruei (d’Orbigny). Division 4 (i) has a fauna closely comparable to that of 3 below. However 4 (ii) contains species of Hoplites (H). transitional from those seen below to those characteristic of the upper part of the spathi Subzone. They are of the grade well represented condensed in Division A of the Maidstone IN THE ANGLO-PARIS BASIN Fic. 16. Correlation of Lower Gault sections at Horton Hall and Folkestone. M Ft pclae : Pel | { a oe Gy Ps ii 6) Em 4 4 4 it Aliv) face ed "ie \ \._ Folkestone i 3 “s VINKi) Bie t 4 (iii) +e i ey +90 - | ith 25. + 80 Alii) i af | (vid +70 li) 204 Ai) = |(v) 7 +60 | Ali) L 157 50 3liv 3iiii) nf 3 ii) 4 3 40 3(i) 4 10- 130 2(vi) 2(iv) r 2(ii) +20 2(i) 5 10i) 10 4 I; 10) ‘o-—o0 39 40 MIDDLE ALBIAN STRATIGRAPHY By-Pass. Division 4 (iii) contains species of Hoplites (H.) that are found in the upper part of the spathi Subzone, and condensed in the ‘ upper dentatus-spathi nodule bed ’ in the northern Weald. In the most northern cut of the old W. field, situated S. of Horton Wood, the top of the spathi Subzone was seen in 4 (ili). This consists of 1 foot 6 inches of shelly clay containing numerous crushed Hoplites (H.) some with well developed lautiform ribbing. The remainder of 4 (iii) in this cut contains numerous Inoceramus con- centricus but no ammonites were found by the author either in these clays or in 4 (iv). Anahoplites intermedius appears in 5 (i) and this level is taken to mark the base of the intermedius Subzone. Before describing the remainder of the Lower Gault here, the correlation of the spatht Subzone sediments with the sequence at Selborne (Owen 1963a ; 43-4) will first be considered (text-fig. 14). Division 3 (i) at the Horton Clay pit contains the same fauna as Beds 1-3 at Selborne. On faunal and lithological grounds, 3 (ii) may be correlated with Bed 4, 3 (iii) with Bed 5, and 3 (iv) with Bed 6 at Selborne. Division 4 at the Horton Clay pit represents Beds 7-9 and the remainder of the sediments of the spathi Subzone not yet exposed at Selborne. The correlation of the Folkestone and Horton Clay pit sections is shown in text-fig. 16. intermedius Subzone The sediments from the base of 5 (i) to approximately 1 foot (0-305 m.) below the top of 5 (iii), a total thickness of 20 feet (6-096 m.), contain a typical intermedius Sub- zone fauna. The ammonites are quite often of good size (up to 4—5 inches (0-127 m.) in diameter) but crushed flat. Anahoplites intermedius, A. praecox, A. mantelli and A. planus are common to within 6 feet (1-829 m.) of the top of 5 (iii) but then decline in numbers above, with Inoceramus concentricus becoming the dominant fossil. niobe Subzone At a level about 1 foot (0-305 m.) below the top of 5 (iti), Dimorphoplites niobe appears sparingly together with Anahoplites planus, Hamuites tenutcostatus and numerous J. concentricus. In 5 (iv) partly crushed ammonites and bivalves occur in the cement-stone nodules, and crushed fossils occur in the interstitial clays ; the stony lenticles are original sedimentary features. The ammonites include Anahoplites planus, Dimorphoplites niobe, D. spp. The same fauna occurs in 6 (1) and (ii). The niobe Subzone is represented, therefore, by 9 feet (2-743 m.) of sediments. subdelaruet Subzone This subzone appears to be represented only within 6 (iii) and has yielded species of Mojsisovicsia including M. subdelaruet and M. remota. meandrinus Subzone Division 6 (iv) contains shell seams which, near the top, yield pyritised fossils. The fauna is typically that which occurs in Bed IV and the basal few inches of Bed V at Folkestone classified with the meandrinus Subzone. Three shell seams at depths of approximately 2 feet 4 inches (0-711 m.), 3 feet 4 inches (1-016 m.), and 4 feet 4 inches IN THE ANGLO-PARIS BASIN 41 (1-321 m.), from the top of 6 (iv) have yielded ammonites suggesting a correlation with the basal 2 inches (0-051 m.) of Bed V at Folkestone. nitidus Subzone A typical nitidus Subzone fauna has been obtained from 6 (v) (Owen 1963a, 46) preserved in a manner identical to that of Bed V at Folkestone. No diagnostic ammonites were found by the author in 6 (vi) or (vii) and it is still uncertain whether these sediments are of nitidus or daviest Subzone age. ? daviest Subzone In 1963, the author stated that the davies: Subzone was absent. However, a few phosphatic nodules from the top of 6 (vii) have yielded ammonites including Ana- hoplites planus and Euhoplites truncatus together with I. concentricus. These occur immediately below the basal cristatum nodule bed at the base of Division 7. In the absence of Anahoplites davies: it is not yet possible to determine whether these deposits represent this Subzone or not. (viii) HASSOCKS TO EASTBOURNE The only section in the Lower Gault now available east of Small Dole is to be seen above the Folkestone Beds in Messrs Hudsons Ltd’s pit at Hassocks (text-fig. 17). Bed Lithology Ft Ins M. White to buff spherical septarian phosphatic nodules in weathered 2 ie) grey clay. A scattered line occurs at the base anda scattered ! 9 Inches above it. ES a Dark grey clay with patches of glauconitic sand which become less be 24 marked upwards. The clay Is well bedded and slightly shaly. > 8 fo) = c x >» ° « | 15 | ee | 7 Loam streaked orange and greylsh with grey clay content ae" 89 increasing upwards and passing down into browntsh loam which fills eres a ows in the bed below. 9 3 10 oH Folkestone Beds Fic. 17. Basal Gault and Gault-Lower Greensand junction beds at Hudsons Ltd’s Hudsons Red Sand pit, 1400 yds W. of Hassocks railway station and 350 yds S. of the B 2116 road, Hurstpierpoint, Sussex (TQ 29121552). 42 MIDDLE ALBIAN STRATIGRAPHY This section has been discussed by Osborne White (1924 ; 29) Kirkaldy (1935 ; 526) and Casey (1961a ; 559-560). The eodentatus Subzone is present within Bed 4, and the lyelli Subzone within beds 4 and ?5. Further east in Sussex there is very little information about the Lower Gault other than that recorded by Clement Reid (1898), Jukes-Browne (1900) and Osborne White (1924 & 1926). Spath demonstrated that at Ringmer the daviesi Subzone is represented (1926a ; 154) and it seems from the well records (Edmunds 1928) that the Middle Albian sediments probably maintain the thickness seen at Small Dole and may well thicken a little. The major increase in thickness of the Gault eastward is mainly explained by the change in facies from Upper Greensand to Gault. This is certainly the case in the Lewes area where the proven Upper Gault is very thick. The discovery of a nodule bed of spathi Subzone age in the sea-bed ESE. of Beachy Head was used by the writer as evidence of an attenuation of deposits of this age in that area (Owen 1963a ; 46, 48, text-fig. 2). However, phosphatised Hoplites (H.) occur in Division 4 at the Horton Clay Pit where the sequence is very thick, and the record of the Eastbourne Waterworks well given by Jukes-Browne (1900, 118) is probably misleading. B. Isle of Wight, and Dorset Coast This section deals with the outcrops in the Isle of Wight, from Punfield to Osming- ton, and from near Seatown to the Devon border (text-fig. 18). Of necessity the account is very incomplete for the exposures are seldom good and the facies is such that ammonites are uncommon except at a few horizons in the various localities. For this reason no correlation diagram is given on this occasion. Despite the difficulties, useful results have been obtained. (i) ISLE OF WIGHT The Carstone, and the overlying Gault (aptly named the ‘ Blue Slipper ’) describe, except in the centre of the Island, narrow outcrops from Redcliff near Culver in the east to Compton Bay in the west. This is in response to the high dip on the northern limb of the Sandown and Brighstone anticlines respectively. | Where the two axes meet in the centre of the Island there occurs a structural ‘ no-man’s land’ with com- paratively gentle northerly dips and thus a broader outcrop. An outlier of Chalk and Upper Greensand in the southern part of the island is fringed by outcrops of Carstone, and Gault dipping gently south. The Carstone and Gault have been described in stratigraphical detail notably by Bristow et al. (1889), Jukes-Browne (1900 ; 126-130), Osborne-White (1921), Kitchin & Pringle (1922a ; 160-161), Spath (1943 ; 741-743), and Casey (1961a ; 512-515), but there are many other references to them in the literature. The Gault is responsible for the major landslips on the southern coastline, and much of the outcrop is obscured by slipping, sludging, and deep weathering. The sections that are available are not always easy to work and fossils are far from plentiful. Fic. 18. Sketch map showing positions of sections in South West England discussed in the text. CARDIFF he a, BEER HEAD @ TAUNTON @ NEwPoRT eaqinroRt 20 6 s stonedarra GoldenCop & . Therneombe Beacon BUDLEIGH SALTERTON ¢ = = up z miles go 0 10 20 km 30 @ BRISTOL @ YEOVIL @ SHERBORNE @ MAIDEN BRADLEY ia a 1 Fitzpane, @ DORCHESTER SQ Hoiworth House Black Head IEY MOUTH PORTLAND WAREHAM . PQOLE nes! UMtHAgton i” @ MARLBOROUGH @ SALISBURY CHRISTCHURCH BOURNEMOUTH ee \STUDLAND aa Cove SWANAGE P PORTLAND BEDS K KIMMERIDGE CLAY C CORALLIAN OC OXFORD CLAY CB CORNBRASH GO GREAT OOUTE 10 INFERIOR OOLITE UL UPPER LIAS ML MIDDLE LIAS LL LOWER LIAS T TRIAS CTS KINGSCLERE @ ANDOVER @ WINCHESTER SOUTHAMPTON @ Outcrop symbols Upper Greensand 0” <_/| Lower Greensand I Purbeck Beds IN THE ANGLO-PARIS BASIN 43 Bristow e¢ al. (1889), Jukes-Browne (1900), and Osborne-White (1921) all give a roughly uniform thickness of 100 feet (30-48 m.) for the Gault throughout the Island. However, this is certainly not correct for although the thickness is about 100 feet (30-48 m.) at Redcliff, it is reduced to about 65 feet (19-81 m.) at Compton Bay, and may be over 100 feet (30-48 m.) in the southern part of the Island. Kitchin & Pringle (1922 ; 160-161) recognised that Middle Albian sediments of the ‘ interruptus Zone ’ were present at Culver and in the south of the Island, but they considered that the Gault in Compton Bay was wholly Upper Gault. They based their conclusion on the old record of Inoceramus sulcatus (Norman 1887 ; 70), but it will be shown below that this argument together with their view that the ‘ —so-called ‘‘ Carstone ”’ of this locality— ’ did not represent the true top of the Lower Greensand, is com- pletely fallacious. Spath (1926b ; 422, and im Jackson 1939 ; 74) considered that the Gault represented only the dentatus Zone and that the ‘ lower benettianus (=inaequin- odum) zone ’ passed into the Carstone beneath. This latter conclusion was confirmed by Casey (1961a ; 515) based on material collected by C. W. Wright and the author. (a) Redcliff The Gault in the hollow between Redcliff and the Upper Greensand face at the W. end of Culver Down (SZ 62758550) is badly slumped and overgrown. However, from time to time exposures of a few feet of clay dipping steeply NE. have been seen near the top and the base of the Formation. The Gault is here about 100 feet (30-48 m.) thick but it is impossible at this time to obtain an accurate measurement. From sections exposed near the base it can be seen that there is a fawn band within six feet (1-828 m.) of the junction with the underlying pebbly Carstone. This fawn band contains crushed Hoplites (H.) spp. with pyritic films replacing the shells, together with a few part-phosphatised specimens. On the basis of the ammonites so far seen, a basal spathi Subzone age is indicated. However, a similar unit at Bon- church has yielded rare but definite lyelli Subzone fossils. Mr. J. McA. Hart collected a pyritised Euhoplites of Upper Gault aspect from a small exposure near the top of the Gault and below Jukes-Browne’s Division A. This indicates that at Redcliff the lower part of the Upper Albian is within the clay facies. (b) Rookley Perhaps the most important section available in the Isle of Wight at this time is exposed in the extensive workings of Island Bricks Ltd., at Rookley. The sequence extends from well down in the Carstone up into the Gault and is shown graphically in text-fig. 19. It has never been described in detail but has been mentioned by Pritchett & Jackson (1941). The pit is cut by an E.-W. fault down-throwing to the south, and the southern part of the section is tectonically disturbed. The sequence north of the fault dips NW. at 6° and shows variations in the thickness of certain beds which cannot be ascribed to a later tectonic cause. These are here considered to be due to slumping before consolidation of the sediment. MIDDLE ALBIAN STRATIGRAPHY Lithology Et Ins M Weathered mottled grey clay, oO © a Ferruginous marl band with phosphatic nodules, 12 Dark grey clay streaked with ochreous seams, 3-4 re 8 4 Ochreous clay with occasional lenticles of ferruginous 1 marl & large spherical or elongated septarian phosphatic nodules ie} 10 Ochreous mottied clay passing down into Bed 9 below. 3 2 7 = io] Qa “” Lo | Highly ferruginous marl. = 9-10 6 8 Dark grey clay with partly phosphatised fossils the shells 2 3 being replaced by films of pyrite. Fawn-grey clay with occasional scattered phosphatic Zz nodules, At base part-phosphatised fossils occur with pyritic shells) — 10-12 ls | Dark grey clay. Ae a awn grey clay, 5 F grey y. — 10-19 4 3 2 4 Dark gritty glauconitic clay, 7S 3 Fawn grey silty clay with burrows of dark grey clay and = 3 crushed pyrite replaced shells of /noceramus concentricus. S 1 3 2 Glauconitic dark grey micaceous clay with streaks of 3 2 glauconite sand, 2 - (il) Streaked grey gritty clay with pockets of sand & glauconite, = 5 (i) Lenticles of false-bedded glauconitic pebbly loam. RQ SS] — 0-6 TOP OF CARSTONE rn Variegated dark and light brown ferruginous grit separated | > 3 8! from Bed1 by a thin seam of iron pan. Top few inches with b Ae 5 many small pebbles and thin seams of pan. Gritty pale = phosphatic nodules occur scattered at about middle. Nine 5 4 6 inches from base there occur crushed ammonites, rarely iy part—phosphatised, with the shell, « ° Fic. 19. Middle Albian sediments at Island Bricks Ltd’s Rookley Brickworks, situated 600 yds ESE. of the school, Rookley, and 150 yds NW. of the A 3020 road, South Arreton, Isle of Wight (SZ 51338395). IN THE ANGLO-PARIS BASIN 45 Bed 5 of the Carstone contains crushed filmy shells of ribbed ammonites. Very rarely these are partly phosphatised and can be identified as Hoplites (Isohoplites) spp. including H. (I.) eodentatus (e.g. BMNH., C 73358 author’s colln., figured Casey 1965 ; 538, text-fig. 202 g.h.) indicating an eodentatus Subzone age. Beds 1-6 of the Gault have not yielded fossils and may represent the /yellc Subzone known to be present in the Ventnor area to the south. Beds 7-11 can definitely be classified with the spathi Subzone. Bed 7 contains crushed pyritic ammonites, some partly phos- phatised, including the typical H. (H.) spathi and H. (H.) dentatus marking the base of the spathi Subzone. Bed 8 also contains crushed Hoplites (H.) spp. with pyritic tests which decompose very rapidly on exposure. Beds g—10 have not yielded fossils, but Bed 11 has yielded a few fragments of large Hoplites (H.) which still suggest the lower part of the spatht Subzone. No fossils were found in Beds 12-14. (c) Compton Bay In view of Kitchen & Pringle’s statement that no Lower Gault is present in Comp- ton Bay (1922 ; 161) it was particularly fortunate that a good section has been ex- posed during recent years. The true Gault here was stated by Strahan (7m Bristow et al. 1889 ; 63) to be 95 feet (28-956 m.) thick excluding the passage beds to the Upper Greensand but this is far in excess of the true figure. The very high angle of true dip seen in the cliff, levels off sharply at no great depth below beach level due to a slight flexure and change in direction of apparent dip. On a very accurate measurement based on the detailed sequence given in text-fig. 20, the thickness is little more than 65 feet (19-812 m.). The phosphatic nodules at the top of Bed 8 of the Carstone have yielded Hoplites (Isohoplites) eodentatus indicating that Subzone. No ammonites have been found in either Beds 1 or 2 of the Gault and their exact Subzonal age is unknown. However, the species of Hoplites (H.) in Bed 3 indicate the basal part of the spatht Subzone and it is possible that both Beds 1 and 2 are of lyelli Subzone age. Apart from Bed 3, the only other ammonites found were crushed Hoplites (H.) sp. at the base of Bed 10, at which point a shelly facies appears. One is tempted to compare this junction be- tween the pyritic facies below and the shelly facies above, with a similar junction in the spathi Subzone sequence in the Nyewood-Wrecclesham area of the outcrop in the Weald. However, such a correlation may well be more apparent than real. Beds 3 to the base of Bed 10 can, therefore, be classified with the sbatht Subzone. Howmuch of the overlying sediments belong to the spathi Subzone is not yet known, as also whether any other Middle Albian Subzones are represented. However, there is no doubt that there is a substantial thickness of ‘ Lower’ Gault present at Compton Bay. (d) Ventnor to Niton A complete section of the Carstone is exposed in the sea-cliff extending from Dunnose south-westwards to the esplanade at Bonchurch ; the stretch of coast named 46 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ins M 20 Deeply weathered grey clay the detailed lithology of which is 12 obscure. In the upper 1 foot the sediment consists of dark grey 6 clay This is followed by Division A of the Upper Greensand. c 3 ° c x c 11 | Very glauconitic silty weathered clay. > fo) 10 Dark silty, micaceous, glauconitic, sparsely shelly clay becoming 0 15 more glauconitic inthe upper 3 feet. We Nn Darkish fine-grained micaceous clay becoming darker upwards 0 1 2 with increase of the silt and very fine-grained glauconite fraction. No fossils seen. 8 Fawnish silty clay containing plant remains at top. oss BI Bed 6 becomes tougher and more silty with scattered pockets of glauconitic silt. Bed 7 in turn passes by wisps into Bed 8, 6 < o Q “” 6 Darkish grey micaceous silty clay with obscure pyritic shell ° fragments. 5 Fawn gritty clay. fe) 5 Dark grey micaceous gritty clay. o 6 Hard blocky silty dark grey clay micaceous and weathering battleship grey. . 2 rs yy Dark grey slightly mottled clayey fine grained micaceous | oam, = weathering light grey. 5 : BASE _ OF THE GAULT ! THE GAUL “ Glauconitic micaceous fine soft silty sandstone with pipes of dark grey clay; £3 bed weathe ferruginous. Small pebbies in clayey bottom 6-8inches, Sandy a) 9 9 of top. oc Oo Fic. 20. Section of the Gault exposed in the sea-cliff about 200 yds NW. of Compton Chine, Compton Bay, Freshwater, Isle of Wight (SZ 36708524). IN THE ANGLO-PARIS BASIN 47 Monks Bay. Above this, the basal beds of the Gault are occasionally well exposed at the top of the cliff, but the remainder of the Gault is badly slumped in the Under- cliff itself. Other sections are known from Ventnor, Steephill, and from Reeth Bay, Niton and round St. Catherine’s Point and are mentioned below. An ammonite described by Spath as Anahoplites mimeticus (1925 ; 131, pl. X, fig. 7a, b) was alleged to have come from the ‘Carstone’ of Niton, Isle of Wight. However, the preserva- tion of the holotype BMNH., C 30535 indicates that it is definitely not from the Carstone but from an horizon in the Gault possibly above the spathi Subzone sedi- ments ; it is possibly a species of Hoplites (H.) with a smooth outer whorl. The specimen figured by Casey (1966 ; 547, text-fig. 207a, b, C. W. Wright Colln., 9983) as Anahoplitoides mimeticus Spath which he states came from the top of the Carstone (eodentatus Subzone), of Bonchurch, is preserved in a manner quite unlike any of the material from the top of the Carstone and C. W. Wright has informed me that it was picked up loose. It must come from a higher horizon in the Gault than the proved spatt Subzone sediments. However, Hoplites (Isohoplites) eodentatus does occur in the top part of the Carstone at Bonchurch but the preservation is the typical sandy phosphate. It might be mentioned here that the specimen of Hoplites vectensis from the Carstone near Niton mentioned by Spath (1925a ; 128 L.F. Spath Colln. No. 238 = BMNH., C 30555) is indeed from the Carstone and is an external mould without the peripheral area. Nonetheless, it is almost without doubt a specimen of H. (Isohoplhites). The few feet of Gault immediately overlying the Carstone at Monks Bay has yielded, from a fawn band, crushed and partly phosphatised Hoplites (H.) spp., specimens of which are in the British Museum (Nat. Hist.) L. F. Spath Colln. An external mould of a Beudanticeras sp. in an identical matrix is preserved in the Institute of Geological Sciences (GSM., Zn 1483 also L. F. Spath Colln.) and indicates the presence of the /yelli Subzone. A pyritic specimen of Lyelliceras is in fact known from this locality and was figured by Spath (1931 ; 320 pl. XXXIII, fig. 15a-c, BMNH., C 32845). Further evidence of the presence of sediments of lyell1 Subzone age is provided by ammonites from the basal Gault near the Gas House, Gas House Hill, Ventnor (SZ 56857747) preserved in the Sedwick Museum. These consist of black brittle phosphate steinkerns without the shell, typical of the lower fawn band, and include Beudanticeras sanctaecrucis and Hoplites (H.) spp., one of them (B 42586) with pyritic inner whorls like that of the Lyelliceras mentioned above. C. W., & E. V. Wright have recorded Protanisoceras moreanum from west of Luccomb Chine (1942 ; 286). More definite information about the higher part of the Gault is provided by the section in the cliff SW. of Steephill Cascade, Ventnor (SZ 55467707). Here the Gault dips seaward becoming much steeper in the foreshore landward of an old slipped mass. Dark grey gritty pyritic clay with rolled pieces of phosphatised Hoplites (H.) spp. occurs along the axis of the ‘ fold ’ and is overlain by sparsely shelly clay in which ammonites have yet to be found. The cliff behind these foreshore exposures is deeply weathered at this time. MIDDLE ALBIAN STRATIGRAPHY Lithology [ae Ins M. = Weathered blocky marly clay with ferruginous streaks. 12 o 16 ? intermedius =e w Homogeneous light grey clay tending to be hard and blocky 16 6 with occasional streaks of silt. Pyritic shell seams occur at 4.and11feet above the base and contain /noceramus concentricus Grey blocky micaceous silty clay with streaks of white silt at base, A pyritic shell seam occurs 2inches from base. Homogeneous grey silty clay. Tough grey silt = 10 © 4 {e) Light fawny grey silty clay with pyritic fossils. 7 Grey silt, Fawn clay with dark burrows, spathi Soft dark grey silty micaceous clay with some fine _ a = wo ~ N SS % a > — aa =a © oO glauconite. 3 6 5 Tough silty homogeneous fawnish clay. 1 6 Bedded pyritic silty clay; the top 4inches being more silty a3 a 4 and glauconitic. 1 8 Blocky grey silty micaceous clay. NV, 1 6 = \ | 3 Obscured interval | | | 3 fo) —--—- - - H-e-F Hee KH — —- ~~ ~— -- |], |! I Mottled pyritic clay, = (= Scape 1 02 — -— = — ae. SS ss — =. foes Si Be Se ee eae a esas ' Obscured interval | o. | I with Was ie) | i] mottled weathered greyclay at the base wi! | : —— 2 Dark grey-brown blocky loam with grey clay streaks, we increasing in number upwards,and some black phosphatic nodules, es 2 os Remainder of CARSTONE Fic. 21. Gault section in cliff below old coast road 50 yds NW. of Cliff Cottage and 360 yds SSE. of Blackgang Hotel, Blackgang, Chale, Isle-of-Wight (SZ 48877644). IN THE ANGLO-PARIS BASIN 49 (ec) Blackgang The section in the Carstone and Gault at Blackgang shows that the sequence has changed fairly considerably in the mere 44 miles from Ventnor. The section given in text-fig. 21 exposed below Cliff Cottage, Blackgang, shows that the sediments are generally coarser in grade. It is exposed at the summit of a cliff of Sandrock Series and in wet weather is dangerous. Bed 8 of the Carstone is probably of eodentatus Subzone age, but Hoplites (Iso- hoplites) has not yet been found here. Unfortunately, the lower 8 feet (2-438 m.) of the Gault is not clearly exposed but it certainly contains at least one fawn pyritic clay band which has not yet yielded fossils. The only ammonite seen in Bed 3 was a crushed Hamuites (H.) sp. 4 inches (0-101 m.) below the top which indicates the spathi rather than the /yelli Subzone. Bed 12 has also yielded crushed Hoflites (H.) spp. which indicate the spatht Subzone. No other ammonites have been found higher in the section but J. concentricus still occurs 11 feet (3-352 m.) up in Bed 13. A section below Gore Cliff about 825 yards SE. of Cliff Cottage shows higher Gault (text-fig. 22). Unfortunately the two sections probably do not overlap although there is an obscured interval of 12 feet (3°657 m.) at the base of the Gore Cliff sequence. I. concentricus is present in the top 1 foot 6 inches (0-457 m.) of ‘ Bed 1’ showing it to be still of Middle Albian age, but no other age indicative fossils are yet known from this section. Certainly some of the lower part of the Gault here is of spbathi Subzone age. How- ever, the specimen of Hoplites aff. vectensis recorded by Spath (1925 ; 128, BMNH., C 890) and said to be from Blackgang is in fact identical in preservation to specimens from the top of the spathi Subzone at Osmington, Dorset, from whence it undoubtedly came. (i) BALLARD CLIFF TO OSMINGTON The early accounts of the Gault in this coastal area of Dorset were given by Strahan (1898) and Jukes-Browne (1900). This work was revised by Wright (im Arkell 1947b ; 178-194), and there is no new information to add to his lithological account for the sections have deteriorated considerably. However, his Subzonal classifica- tion of the basal beds requires revision. Wright redescribes, as far as it is possible, the sections at Punfield Cove, Swanage (SZ 03878110), Flower’s Barrow, Worbarrow Bay (SY 86388045), Lulworth Cove (East SY 82867988, West SY 82427988), Durdle Cove (SY 80578028), White Nothe, and Black Head, Osmington, covering in all a distance of 35 miles (text-fig. 18). Beds 1 and 2 at Flower’s Barrow, Worbarrow Bay, are apparently of the same age as the ferruginous clay with concretions at Black Head, Osmington, as Wright stated. However, the fauna from these sediments at Black Head, first recorded by Cunning- ton (1929) is not of ‘ benettianus ’ Subzone age as Spath originally thought (Wright im Arkell 1947b ; 181) for all the species of Hoplites (H.) which occur, such as H. (H.) dorsetensis and H. (H.) vectensis, can be matched in the highest part of the spathi Subzone in the Weald and elsewhere. Even Spath was to change his mind about the Subzonal age of these two species, placing them in the imtermedius Subzone (1942 ; ’ D 50 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ins M 9 : Dark grey silty clay with wisps of glauconite and sand, shelly with scattered pyrite nodules. o 8 z 5) Homogeneous dark grey clay with pyrite nodules and crushed fossils with the shell preserved, 6 ‘4 Blocky homogeneous dark grey clay with pyrite nodules and 4 6 occasional bivalves with the shell preserved. Passing down at the base into; Glauconitic silty clay with rafts of glauconite sand, 595 | Fawn clay with pyritic nodules, and phosphatic nodules at the top, 5 4 4p Dark grey glauconitic silty clay with Inoceramus concentricus 6 _ preserved with the shell. ean eed at 3 Sequence obscured by scree, 0 2 1 ° ExGs22; Cliff section of Gault at top of undercliff below Gore Cliff, 480 yds ESE. of South View House, Blackgang, Chale, Isle of Wight (SZ 49437590). IN THE ANGLO-PARIS BASIN 51 675). In this, he was very nearly right, for the concretions at Black Head yield, albeit very rarely, early forms of Anahoplites of the intermedius group. These include the specimen figured by Spath as A. mimeticus (1927 ; 188, pl. XVII, fig. 8a, b) which belongs to A. osmingtonensis sp. nov., and A. grimsdalei sp. nov. which is the direct forerunner of A. evolutus a form found at the base of the intermedius Subzone. These early Anahoplites are associated with the usual species of Hoplites (H.) of this bed, however, it is important to note Cunnington’s remark (1929 ; 126) : ‘ Ana- hoplites—are scarcer, but wherever one is found there are almost always others or fragments of others in the same block’. Ihave not yet found Anahoplites in this line of concretions containing an upper spathi Subzone fauna. This might be purely a collecting error, for the matrix and mode of preservation of the specimens of Ana- hoplites is identical to that of the other fossils of this bed and this is very distinctive. From a morphological point of view these are unquestionably earlier than the basal intermedius Subzone species of this genus, e.g. A. evolutus (p. 151). Equally certain, they are not earlier than the high spathi Subzone concretions ; that is, they are not of lyelli Subzone age. The sections in this area are shown in Arkell (1951 ; Fig. 4). Deposits of Jautus Zone age are also present in this area (Cunnington 1929 ; 129 : Spath 1943 ; 743 : Wright 7m Arkell 1947 ; 193) but the position in the section of the material picked up loose has yet to be determined. (iii) THORNCOMBE BEACON TO BLACK VEN The account of the sections on Golden Cap, and Black Ven, given by Jukes-Browne (1900 ; 182-189) was followed fourteen years later by the very important detailed account by Lang (1914) who also discovered the formation on Stonebarrow. To this, additional information was added in Lang & Thomas (1936), and these sections to- gether with that on Thorncombe Beacon east of Seatown have more recently been described by Welch (im Wilson, Welch, Robbie & Green 1958 ; 139-150). Here again, there is nothing to add to the lithological account but a re-examination of the ammonites has provided a little, but important, additional information. The sediments classified with the Gault are much thinner in this area of the coast. Bed 1 of Lang (1914) yielded Anahoplites praecox both at Black Ven and Stone- barrow (1936 ; 310). Bed 2 on Stonebarrow has also yielded A. praecox including one specimen BMNH., C 15661 which is very close indeed to the neotype of ‘ Dimor- phoplites’ alternatus, which is in reality a very coarse development of A. praecox (p. 153). A. praecox also occurs at Charton Goyle in a matrix which is almost cer- tainly the unweathered representative of Bed 2 (BMNH., C 68394-6). Beds 1 and 2 definitely belong to the intermedius Subzone. According to Spath (e.g. 1943 ; 744), Bed 3 contains both intermedius Subzone and varicosum Subzone ammonites. This is untrue. BMNH., C 41035 from Bed 3, recorded by Spath as Epihoplites aff. trifidus, is in reality an early transition between Hoplites (H.) and Dimorphoplites consistent with an intermedius Subzone age. The ‘ Idiohamites of the turgidus group’ (BMNH., C 41038) is a Protanisoceras (H.) cf. nodosum, also indicating an intermedius Subzone age. Another specimen BMNH., C 41035 from Bed 3 is here identified as Anahoplites cf. intermedius. 52 MIDDLE ALBIAN STRATIGRAPHY There is, therefore, no evidence of the presence of Upper Albian sediments in Lang’s Bed 3 and this is consistent with the distribution of Inoceramus concentricus and J. sulcatus. I. concentricus is known from Beds 1, 2, and 3 (e.g. Lang Colln., BMNH., L 55076 from Black Ven) both on Black Ven and Stonebarrow. Specimens of I. sulcatus are known from Black Ven (e.g. BMNH., L 55368-71 Grimsdale Colln.) preserved without the shell in glauconitic sandstone which suggests Lang’s Bed Io, certainly no lower horizon. The record of Anahoplites planus from Lang’s Bed 10 by Spath (1943 ; 744) isanerror. The Middle-Upper Albian boundary falls somewhere between the top of Bed 3 and ?the base of Bed Io. The above indicates that Kitchin & Pringle’s statement that no Lower Gault exists at Black Ven is quite fallacious (1922 ; 163). This statement is the more incredible when one realises that they had never examined the section and apparently had overlooked Lang’s paper of 1914. There may well be a non-sequence in these sections but at this time there is no evidence to indicate its extent. No sections further west on the Devon Coast have been examined by the writer. (iv) CONCLUSION The poor state of the sections in the Isle of Wight and on the Dorset Coast are particularly tantalising, nonetheless, some results can be drawn from this incomplete information. It is apparent that in the Isle of Wight the eodentatus Subzone is represented at the summit of the Carstone ; the /yells Subzone is represented in the lower part of the Gault at least in the southern part of the island ; and the spathi Subzone sediments are well developed. The intermedius Subzone is probably repre- sented but the conclusive proof is not yet to hand. By Worbarrow Bay and Osmington the fossiliferous concretions very near the base of the Formation are of uppermost spathi Subzone age, and there is evidence of lautus Zone sediments near the top of the Gault in the Osmington-White Nothe area. In the sea-truncated outliers between Seatown and Lyme Regis the lowest fossilifer- ous sediments are of intermedius Subzone age. As one proceeds westwards from the Isle of Wight, therefore, the lowest fossiliferous sediments become later in age (text- fig. 23). The intermedius Subzone is widely represented by sediments in the deeper parts of the Wessex Basin ; for example in the Petersfield and Winchester districts, Hampshire (p. 69), at Didcot, Berkshire (p. 63), Devizes, Wiltshire (p. 60), and possibly at Okeford Fitzpaine, Dorset (p. 56). Its presence in the Isle of Wight, and in the Dorset coast sections as far west as Osmington should not be. discounted. Across the Channel at Cauville on the French coast NE. of Le Havre, there occurs, above a vemanzé bed of basal dentatus Zone age, even later sediments of niobe Subzone age (p. 107). C. The outcrop from Devon to Bedfordshire There is no information available about Middle Albian sediments inland in the area W. of the River Axe. Neither is there any further stratigraphical information available at the outcrop from the valley of the Axe to Okeford Fitzpaine, N. Dorset, a IN THE ANGLO-PARIS BASIN 53 other than that recorded by Jukes-Browne (1900 ; 163-4), Welch and Robbie (in Wilson, Welch, Robbie & Green 1958 ; 148-152)', Reid (1903 ; 34-35), Osborne- White (1923 ; 49-50) and Smart (1955 ; 43-4). It is apparent that Middle Albian sediments occur north-eastwards from the area of Beaminster for although am- monites have not been found, IJnoceramus concentricus has been recorded from a number of sections and in this context definitely indicate a Middle Albian age. From the coast between Thorncombe Beacon and Black Ven (p. 51), Middle Albian sediments thin markedly inland in places to less than Io feet (3-04 m.) to thicken again in the area of Toller Porcorum (SY 562974) S. of Evershot, and also in the out- crop N. of Evershot eastwards from West Chelborough (Welch and Robbie 7m Wilson et al., 1958). The Gault continues to thicken eastwards and in the region between Alton Pancras and Ansty, Smart records a thickness ranging from 25-35 feet (1955 ; 42-4). The increasing thickness is maintained up to Okeford Fitzpaine. Ww B Black Ven Osmington Isle of Wight Sussex intermedius (garly) Fic. 23. Sketch section, from W. to E. across the Late Jurassic-early Cretaceous modified Wessex basin in the area of the south coast, demonstrating the transgressive nature of the Middle Albian sediments and the diachronous nature of the base. It is very regrettable that no good sections are now available throughout this long strip of outcrop (text-fig. 18). The sequence seen on the coast between Thorncombe Beacon and Black Ven, with its development of the intermedius Subzone of the loricatus Zone has passed in the area of Okeford Fitzpaine to a sequence showing the development of the eodentatus, lyelli & spathi Subzones of the dentatus Zone. In this latter area it is underlain by deposits of mammullatuwm Zone age absent at the coastal section to the SW. This difference in sequence is made somewhat significant by a comparison with the sections in the Pays de Caux in northern France (p. Ior), and is discussed later in the section dealing with the conditions of deposition (p. 142). 1 It is worth stating here that the stream and river sections described by the Survey officers are only well visible in periods of drought (cf. Dewey 1934 ; 42). 54 MIDDLE ALBIAN STRATIGRAPHY (i) OKEFORD FITZPAINE (DORSET) The section at the Okeford Brick & Tile Works situated about 4 mile E. of the village of Okeford Fitzpaine on the road to Shillingstone is no longer visible. It was first described by Newton (1896 ; 198 : 1897 ; 66-68) from notes and material provided by the Misses Forbes and Lowndes, then by Jukes-Browne (1900 ; 162), Reid 1903 ; 34-35), and Osborne White (1923 ; 48). Text-fig. 24 is taken from the account given by Newton (1897, 67-8) with additions from Jukes-Browne. Spath (1925 ; 73 pl. V, fig. 6) figured one of Newton’s specimens of ‘ Acanthoceras mammillatum’ as Douvilleiceras inaequinodum (Quenstedt) so demonstrating the presence of the inaequinodum Subzone to which Casey assigns the base of the Gault here (1961a ; 565) ; now included in the eodentatus Subzone. Spath also demonstrated the presence of the benettianus Subzone (i.e. lyelli Subzone) by the occurrence of Hoplites (H.) ‘ pseudodeluci’ Spath (type locality, 1925a ; 120) and forms close to H. (H.) benettianus (J. de C. Sowerby) (1925a ; 117-8), together with Beudanticeras probably laevigatum and ‘Anahoplites of mimeticus type’ (1926a ; 147). The material described by Newton is in the British Museum (Nat. Hist.). A re- examination of the fossils and a careful reading of Newton’s account (1897) has provided the following important stratigraphical information. All the specimens were undoubtedly indigenous and not semi-derived. The three fragments (BMNH.., C 6856-8) recorded by Newton as Acanthoceras mammuillatum described by Spath as Douvilleiceras inaequinodum could well belong to one partly phosphatised individual. The nacreous shell was clearly preserved and the matrix adhering to it consists of the bluish grey micaceous clayey sand with glauconite of Bed3. Thespecimen could not, therefore, have come from Bed 2. The specimens of Ostrea leymeriet (BMNH., L 11579 figured specimen, L 11591) have traces of the same sediment adhering to them as that of the specimen of D. inaequinodum. Moreover, internally there is the same blackish phosphate. It would seem also that these come from Bed 3 and not Bed 2 (cf. Newton 1897 ; 68). If this is the case then Bed 2, which Jukes-Browne (1900 ; 163) considered to be a separate lithological unit and from which he records no fossils, together with Bed 1 may correspond to sediments at Dinton in the Vale of Wardour which have yielded a kitchint Subzone fauna (Casey 1956 ; 231, 196Ia ; 564). Jukes-Browne considered that these two beds should possibly be grouped with the Lower Greensand. My reading differs from that of Casey (1961a ; 565) who states that the Gault here rests directly upon the Kimmeridge Clay. Two fragments of large specimens of Hoplites (H.) spp. (BMNH., C 6859-60) identified by Newton as Hoplites benettianus (1897 ; 70), one of which he figured, are preserved one with and the other without the nacreous shell in a ferruginous brown (weathered) and grey micaceous clayey sandstone. Bearing in mind Newton’s remarks (1897 ; 67-8) this lithology indicates the upper part of Bed 4. The specimen figured by Newton (1897 ; 70, pl. 2, fig. 1, BMNH., C 6860) was subsequently made the holotype of Hoplites pseudodeluci by Spath (1925a ; 120-123) but due to its crushed state and lack of inner whorls the true nature of it is impossible to determine. Moreover, a specimen from Bed 5 at Badbury Wick shows a closely comparable outer IN THE ANGLO-PARIS BASIN 55 Lithology (li) Dark-grey micaceous silty clay with phosphatic nodules. ?spathi (1) Shelly dark-grey silty clay with glauconite. lyelli Brown sandy rock with fossils inthe upper part. Brown, green grey, and yellowish clayey micaceous loam, with part phosphatised fossils with the shell preserved, and small pebbles particularly In the lower part. Brown sandy Ironstone breaking Into small lumps, ? kitchini Clean green sand, D i) a € — — — — ee ee - - - = EF - - - - - eodentatus KIMMERIDGE CLAY Fic. 24. Section in Albian sediments (after Newton 1897, Jukes Browne 1900, & Osborne White 1923) formerly exposed at the old Okeford Brick & Tile Works, immediately S. of the Okeford Fitzpaine to Shillingstone road, 800 yds E. of St. Andrew’s Church, Okeford Fitzpaine, Dorset (ST 81501080). 56 MIDDLE ALBIAN STRATIGRAPHY whorl but the inner whorls are those of H. (H.) bullatus Spath. Bed 4 can definitely be classified with the lyelli Subzone even if no specimens of Lyelliceras, Beudanticeras or Protanisoceras have been preserved. A more typical lyelli Subzone fauna was recovered from the lower part of Bed 5. The ammonites described by Newton are preserved in two distinct lithologies, although they all possess remains of the nacreous shell and, except for one, are preserved as partly crushed clay steinkerns. They were re-identified by Spath as follows, to which my own comments are added. Hoplites interruptus Bruguiére (1) Hoplites pseudodeluct Spath (BMNH., C 6864) figured by Spath (1g925a ; 121, pl. X, fig. 6) which is preserved in an identical manner to those of Bed 4 from which it probably came. (2) Hoplites sp. transitional between benettianus & paronar (BMNH., C 6863) according to Spath (1925a ; 115, 118). This specimen which has pyritic inner whorls is crushed ventrally, having come to rest on the sea floor on its venter. It is pre- served in fawn clay with glauconitic loam filled burrows. It is specifically indeter- minate. (3) Hoplites sp. benettianus, baylet group (BMNH., C 6862) (1925a ; 118) probably does not belong to either of these two species. (4) Newton’s figured specimen (BMNH., C 6861), identified by Spath as Hoplites dentatus (J. Sowerby) (1925a ; 118), is preserved crushed in glauconitic sandy dark grey clay. Hoplites splendens J. Sowerby (5) The two small specimens (BMNH., C 6866-7) were identified by Spath as Beudanticeras probably laevigatum. They are preserved in exactly the same type of matrix as (2) above. (6) The larger specimen (BMNH., C 6865) was identified by Spath (1926a ; 147) as Anahoplites resembling A. mimeticus. It certainly is an Anahoplites, preserved in the same type of matrix as (4) above, and its occurrence is discussed below. Hamites sp. (7) In his description of Hamites attenuatus Spath (1941 ; 611 footnote) referred to the two specimens indicating that they might have been tuberculate and, therefore, generically distinct. A close examination shows that they are both Protanisoceras sensu-stricto, one of them (BMNH., C 6868) being P. (P.) barrense, the other (BMNH., C 6869) closely comparable to that species. They are both preserved in the same lithology as (2). The specimens (Nos. 2, 5, & 7 above) preserved in fawn clay with darker glauconitic burrows are certainly a lyelli Subzone assemblage. The two specimens (Nos. 4 & 6) preserved in glauconitic sandy dark grey clay suggest, however, a high spatht Subzone age. It has been suggested above (p. 47) that the type of Anahoplites mimeticus is a spathi Subzone species of Hoplites (H.) and certainly did not come from the Carstone, of the Isleof Wight. The association of Anahoplites of the osmingtonensis-grimsdalet group with species of Hoplites (H.) in the Osmington area of Dorset which Spath | | IN THE ANGLO-PARIS BASIN 57 (1926b ; 422) considered to be of benettianus Subzone age in fact marks the extreme summit of the spathi Subzone (p. 51). This association is also to be seen at the summit of the spathi Subzone at Caen Hill, Devizes (p. 60) and probably also at Dilton Marsh. (i) VALE OF WARDOUR TO DEVIZES (WILTSHIRE) (a) Vale of Wardour No sections in Middle Albian sediments are now to be seen in the Vale of Wardour. A brickyard was worked throughout much of the 19th Century near Ridge and was first described by Fitton (1836 ; 247) and was listed by d’Orbigny (7m Geinitz 1849) as ‘Rudge’. Jukes-Browne (1900 ; 230), Reid (1903 ; 32, 39), and Andrews (in Andrews et al., 1903 ; 158) provided further information about this section. Fitton’s ‘ Am- monites rhotomagensis ’ suggests Lyelliceras lyelli indicating the lyell1 Subzone but the specimen has not beentraced. Both Fitton and Jukes-Browne record Inoceramus sulcatus as well as I. concentricus from this area and the varicosum Subzone is certainly present in marls at the Watercress beds Fovant (Mottram 1957 ; 166, 1961). The only other sections are a well at Dinton described by Jukes-Browne & Andrews (1891 ; 292 & 1900 ; 228 : and mm Reid 1903 ; 31, 38), and an exposure of the basal beds in Wardour Park (Reid 1903 ; 34, Mottram 1957 ; 161). Casey demonstrated (1956 ; 231, 1961a ; 565) that the lower part of the sequence in the Dinton well was of kitchini Subzone (Lower Albian) age and was overlain non-sequentially by clays of dentatus Zone age. However, no fossils have been preserved from the clays and it is impossible to determine their subzonal position. At the present time it is not possi- ble to correlate these three sections with each other, or any section south or north of the Vale. (b) Maiden Bradley to Devizes No sections now exist in this area of the outcrop, although brick pits formerly existed at Redford Water, Flintford, Crockerton, and Westbury, all described by Jukes-Browne (1900 ; 235-6). From his account of them it is possible to gain some idea of the lithological sequence in the lower part of the Gault in this area (text-fig. 25). The Crockerton section was worked in the early part of the rgth Century and yielded to Miss Benett the holotypes of Ammonites benettianus and Ammonites _ laevigatus described by J. de. C. Sowerby. It also probably yielded the specimen of Ammonites monile mentioned by Fitton (1836 ; 258) and a good deal of the English lyella Subzone ammonites in the various collections used by Spath in his Monograph of the Ammonoidea of the Gault. Until the late 1930’s it was the only section known in England to have exposed sediments definitely containing Lyelliceras lyelli. There is now a factory on the site. Unfortunately, there are no detailed accounts either of this section or the others mentioned above. However, Jukes-Browne’s account (text-fig. 25) suggests that the sequence is fairly uniform. It appears that ‘ Division’ 3 definitely yielded lyelli 58 MIDDLE ALBIAN STRATIGRAPHY Subzone fossils and by comparison with Caen Hill, Devizes (p. 60), probably was the source of some spathi Subzone ammonites also known from Crockerton. In the Westbury area, the Eden Vale Brickyard described by Jukes-Browne (1900 ; 236) is no longer exposed, but the pit worked by the Westbury Potteries Ltd., has shown sections of the basal beds of the Gault from time to time. Casey (1956 ; 233 : 1961a ; 564) has referred to this section as the Bremeridge pit demonstrating the presence of the kitchini Subzone overlain non-sequentially by the basal beds of the Gault of dentatus Zone age. This pit is presumably the source of the specimen of ‘ Anahoplitoides’ from Dilton (Ponsford Colln.) illustrated by Casey (1966 ; 547 text-fig. 207c). REDFORD WATER FLINTFORD CROCKERTON EDEN VALE M Ft 9-730 25 3 3 3 6720 15 ? ate Za Lk 4 ee : 1 1 o+0 er Fic. 25. Possible correlation of sections in the Warminster area of Wiltshire described by Jukes-Browne (1900 ; 235-6). (c) Caen Hill, Devizes The area W. of Devizes has been a centre of brick and tile production since the latter half of the last century. The sections then exposed at Caen Hill and Dunkirk were described by Jukes-Browne (1892 : Ig00 ; 249-250, 252: 1905 ; 15-16) and Osborne-White (1925 ; 39). Old collections in the British Museum (Nat. Hist.) and Institute of Geological Sciences indicate the presence of the ?eodentatus, lyelli & spathi Subzones in this area, and some of the ammonites were described by Spath (1923-1925). IN THE ANGLO-PARIS BASIN Bed Lithology Light grey weathered clay with limonitic concretions after pyritic ?fossils, Weathered grey clay. Pyritic dark grey clay weathering ferruginous. Weathered blocky silty micaceous dark grey clay with bleached areas at parting planes. Poorly bedded massive micaceous silty clay, rather more silty in the lower 1foot Sinches, with many pyritic filaments. A snell seam occurs 3 feet from the base and contains brown phosphatic concretions. The clay, darkish grey in colour, contains scattered shells with a few large crushed ammon- ites in the sediments above the 3 feet level. grey clay. (iii) Tough silty glauconitic dark grey clay with a few scattered shells. (ii) Part-phosphatised ammonites &cementstone nodules in burrowed clay. (i) Passage bed between lithology of Beds 4and S({iii), Fawn silty clay with glauconite-sand infilled burrows. Finely silty micaceous clay, coppery brown in colour when wet and fresh, with patches of dark grey clay. Both are cut by fawn coloured burrow infillings 1m top Binches. Pyritic filaments occur throughout; shelly especially in the upper part. Prominent and persistant seam of sandy ferruginous marlistone. Medium grey clay with some phosphatic nodules. \ (v) Blocky massive grey clayey silt, weathering white. The top 12inches contains more clay. (iv) Dark grey silty clay with filaments. (Gi)Grey clayey silt with pyritic filaments; passing at the base into 8(ii), (ii) Sparsely shelly glauconitic grey clay with pyritic filaments. in > (i) Very silty micaceous clay with pyrite and lenses of siltstone. = Ww = & wu ~ = Brownish fawn silty clay, extensively burrowed, with infillings of dark Wy SPATHI 42 10 os 14— 134 12 | 10 244 Fic. 26. Section in Gault at Messrs Hills of Swindon Ltd’s Caen Hill brickyard, c. 180 yds ENE. of the Olive Branch Inn, in the W. side of Caen Hill, Rowde, Wiltshire (ST 98246135). 60 MIDDLE ALBIAN STRATIGRAPHY The presence of the eodentatus Subzone is suggested by Cleontceras? devisense Spath (19238 ; pl. IV, fig. 7a, b) and Hoplites cunningtoni Spath (1923< ; 109, pl. VIII, fig. 8a, b). Specimens of Cleoniceras (C.) are known from the eodentatus Subzone in France but they are very rare and Mrs. P. Jennings has obtained one undoubted lyelli Subzone example from Badbury Wick. Hoplites cunningtont isa late Otohobplites, a genus also known to occur in the eodentatus Subzone elsewhere in southern England and in France. The /yelli Subzone is indicated by ammonites such as Beudanticeras laevigatum and Hoplites (H.) baylet, and the spatht Subzone sediments are still ex- posed. The most important result of the present study is the discovery of a reasonably thick sequence of sediments of intermedius Subzone age at Caen Hill. This occurrence and that at Didcot (p. 63) represents the first time that the subzone has been recorded in this area of the outcrop in Wiltshire and Berkshire. Spath (1943 ; 745) followed Osborne-White (1925 ; 39) in considering that the lautus Zone was present in the Gault of the Devizes area. This opinion was based on material obtained by Cunnington from the long since vanished brickpit at Dun- kirk. However, Jukes-Browne (1900 ; 252, 1905 ; 16) lists Inoceramus sulcatus as well as J. concentricus and it is quite possible that this indicates the orbignyi Subzone. This particular record of the Jautus Zone should be treated at this time with caution. The brick pit at Caen Hill is still in work. It was formerly owned by the Devizes Brick & Tile Co. Ltd., but now by Messrs Hills of Swindon Ltd. It is situated on the W. side of Caen Hill and has been worked eastwards into the hill exposing the section given in text-fig. 26. A dip of 3° towards the E. is present. The lyelli Subzone sediments are seldom exposed now, and no satisfactory section has been seen by the writer. It is possible that ‘ Division’ 4 (text-fig. 25) of the Warminster-Devizes area is the same as Bed 2 of my section. If this is the case then the pre-spathi Subzone sediments are thick at Caen Hill. Beds 1 to 5 contain Hoplites (H.) spp., such as H. (H.) dentatus and H. (H.) maritimus, indicating the spatht Subzone together with a good benthonic fauna of bivalves and gastropods. A shell seam 3 feet (0-914 m.) above the base of Bed 7 contains crushed evolute Anahoplhites of grimsdalet type and ribbed forms comparable to A. evolutus and A. osmingtonensis together with occasional specimens of Hoplites (H.). This association continues through part of the remainder of Bed 7, and these sediments are here considered to be a little later than the concretions in the Osming- ton area, Dorset (p. 51) which are classified with the uppermost part of the spat Subzone and may be represented at Devizes by Bed 6 and the basal 3 feet of Bed 7. However, at Devizes in Bed 7 the situation is reversed, Hoplites (H.) being here sub- ordinate to Anahoplites, and so these clays are classified with the basal part of the intermedius Subzone. This level is, therefore, closely comparable to the basal part of the intermedius Subzone in the Départements of the Meuse (p. 88) and Aube (p. 93). In the Weald, this interval does not contain ammonites. The remainder of Bed 7, and particularly 8, contains a typical intermedius Subzone fauna with crushed Anahoplites praecox and A. intermedius. No fossils were ob- tained from Beds 9-11 and their subzonal classification is, therefore, unknown at this time. ee (2 — &- = eae a> a0 IN THE ANGLO-PARIS BASIN 61 (i) DEVIZES TO THAME (OXON) (a) Badbury Wick (Wiltshire) There is no information available at the outcrop between Devizes and the Swindon area, a distance of about 18 miles (text-fig. 18). Messrs Hill’s of Swindon Ltd’s pit at Badbury Wick has shown a section in spatht Subzone sediments for some years, but in 1967 the pit was deepened and exposed sediments of lyelli Subzone age. The sequence now exposed is shown in text-fig. 27. Although this is the first time in this century that a lyell1 Subzone sequence has been well exposed in Wiltshire, it is apparently different from that of Caen Hill and further south-west (text-figs. 26 & 25). A working near the present pit was mentioned by Ramsey, Aveline & Hull (1858 ; 33). Beds 1 to 6 contain a typical lyelli Subzone fauna but in contrast to Small Dole (p. 38) Lyelliceras lyelli and Brancoceras spp. occur only infrequently and the bulk of the fossils are crushed. The commonest ammonites are the heteromorphs such as Protanisoceras (P.) barrense and P. (P.) alternotuberculatum together with Beudanticeras laevigatum, and Hoplites (H.) spp. The facies is a shelly one, albeit sparsely in places, with in general a better developed benthos than that seen in Sussex. Ammonites are apparently rare in Bed 6 which otherwise contains very well preserved but fragile bivalves and gastropods. That it still belongs to the /yelli Subzone is indicated by the occurrence of Beuwdanticeras spp. as well as Hoplites (H.) spp. Beds 7 to 11 are classified with the spathit Subzone. Bed 7 shows the major change in the ammonite fauna which marks the base of the sfathi Subzone, and these now consist of species of Hoplites (H.) such as H. (H.) dentatus and H. (H.) maritimus sp. nov. associated with the bivalve Inoceramus concentricus in shell seams. The benthonic fauna is very reduced in comparison with the lyelli Subzone sediments below. Bed & contains the same fauna with individuals partly phosphatised with the shell, while in Bed 9 the fossils are again crushed flat. In Beds 10 and 11 the shells are replaced by pyrite and the non-ammonite element of the fauna becomes un- common. No fossils have been found in Bed 12 and its age is uncertain. The lithological sequence in the spathi Subzone is quite different from that of Caen Hill, Devizes (text-fig. 26), where there is no pyritic facies in any part of the spathi Subzone sequence and a good benthos is present throughout. The sequence at Badbury in this Subzone is surprisingly reminiscent of that exposed in the Nyewood- Selborne area of the western margin of the Weald (Owen 1963a). However, there, the situation is somewhat reversed, the pyritic facies encompassing the sediments up to and including the two ferruginous marly bands, the shelly facies prevailing in the higher beds. (b) Badbury to Thame The Gault outcrop in the Vale of White Horse (Berkshire) has been discussed principally by Hull & Whitaker (1861), Jukes-Browne (1900 ; 268) and Arkell (19472 ; 167-9). No sections now exist either at Uffington or in the area N. of Childrey. Arkell recorded the discovery of specimens of Dimorphoplites by Mr. C. W. Wright in 62 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ins M. Micaceous, glauconitic, very clayey burrowed silt. Weathered light-grey pyritic clay with a few shell seams, the shells being replaced by pyritic films. Ferruginous pyritic marl, weathering rusty, with phosphatic nods. spathi Fawnish-grey slightly micaceous shelly clay. Fawn marly clay weathering ferruginous with part-phosphat ised fossils and a few phosphatic nodules, The bed is shelly. Shelly highly glauconitic dark grey clay with more glauconitic silty bands, The clay is micaceous, and pyritic filaments occur scattered throughout. Pockets of glauconite occur also, together with some burrows infilled with grey 7 silt. Although still shelly, the basal 18 inches does not contain ammonites and is immediately overlain by a 12inch seam of highly glauconitic silty clay. A bedding plane 4 inches below the top contains pyritised ammonites with their shells preserved, Dark grey gritty micaceous shelly clay becoming more plastic downwards, Fawn grey plastic clay, shelly, with a few burrows, Scattered black septarian phosphatic nodules at top, anda few similar ones occur to 1 foot below the top. A few pyritised ammon- ites occur scattered throughout, together with large part phosphatised ammonites in gritty concretions 4-Sinches from base Tough dark grey gritty clay shelly with large black phosphatic nodules at top, & scattered septarian phosphatic nodules at base! tyelli Fawn grey plastic, silty, micaceous, sparsely shelly clay, with 3 numerous pyritic filaments and part-phosphatised fossils at base. Brownish fawn shelly clay, burrowed, with dark fawn infillings; passing down into Bed 1. eas) Dark fawn-grey clay. Fic. 27. Section in Gault at Messrs Hills of Swindon Ltd’s Badbury Brickworks, W. of Day House Lane, 200 yds SW. of Badbury Wick House, Chiseldon, Wiltshire (SU 18828160). IN THE ANGLO-PARIS BASIN 63 the Childrey section (1947a ; 169) and I have been kindly allowed to re-examine them. They are, as identified by Mr. Wright, a specimen of Dimorphoplites biplicatus (C.W.W., 9762) and a specimen of D. glaber (C.W.W., 9761). Together they indicate an horizon somewhere between the base of the meandrinus and the top of the daviesi Subzones. Nine miles ENE. of the Childrey brickyard is the famous section at Culham (Oxon). This pit situated approximately 200 yds. N. of the River Thames, 425 yds. E. of the road bridge over Culham Cut and 700 yds. SSW. of Culham College, Culham, Oxon (SU 51159487) was in work from the middle of the last century until the late 1940’s. It has been described by Phillips (1860 ; 548-550, 1871 ; 426-428), Jukes-Browne (tg00 ; 268-9, 1908 ; 13-14), Osborne-White (1904 ; 300-304), Treacher (1908 ; 548-550) Pringle (1926 ; 101-2), and Arkell (1947a ; 169-170). Osborne-White’s account paved the way for the more detailed description given by Pringle, but the section is now badly degraded and overgrown and it is not possible to confirm or deny Pringle’s subzonal grouping repeated by Spath (1943 ; 745-6). Neither is it possible to make a direct comparison with the sequence at Badbury Wick. From the list of fossils collected by Osborne-White (Jukes-Browne & Osborne-White 1908 ; 14) from Bed 3 (= Bed 1 of Pringle 1926) it seemed possible that either the mammillatum Zone was present or possibly the eodentatus Subzone. Douvilleiceras does range up into the lyella Subzone but is rare in that Subzone in England except at Shere. Casey, who has revised the identification of the ammonites, is in favour of a basal dentatus Zone age (19g61a ; 565), and it is significant that Osborne-White records ‘ Hoplites interruptus ’ just above Bed 2 (1904 ; 304). Beds 2 and 3 of Pringle were classified by him with the ‘ benettianus Subzone ’, and Beds 4 and 5 with the spathi Subzone. From the ammonites preserved in the various collections it is apparent that both the lyella & spathi Subzones are present. It is interesting to note that in the remnant of Gault formerly exposed at the abandoned Chawley Brickyard, Hurst Hill (SP 47550420), Cumnor, Pringle (1926 ; g8, 103) recorded ammonites which he considered to be characteristic of Bed 4 at Culham. This section was situated 7 miles NNW. of Culham and has also been discussed by Arkell (in Richardson, Arkell & Dines 1946 ; 104). If the equivalents of Beds 1 to 3 are truly absent in this outlier, this is of some palaeogeographic significance. The only other useful information yielded by this area is provided by two borings, Nos 6 and 21, drilled for the new Central Electricity Generating Board Didcot Power Station (SU 51289174 & 51339194 respectively). Together, the fragments of these two cores show the following features in the sequence. The orbignyi Subzone is in a Gault facies, indicated in Boring No. 21 by a fragment of core containing Inoceramus sulcatus preserved in mid-grey micaceous silty clay with lighter coloured burrows from a height of 122 feet 6 inches (37:34 m.) above the base of the Gault. The intermedius Subzone is also present at a height of 68 feet (20-73 m.) above the base of the Gault in Boring No. 6 where the core yielded a crushed specimen of Anahoplites praecox preserved with a pyrite-replaced shell in silty brownish grey clay (cf. Bed 8 ii at Caen Hill, Devizes, p. 60). Boring No. 21 shows that the spathi Subzone with Hoplites (H.) spp. is certainly present in the sequence between 42 feet 6 inches and 17 feet 6 inches (12:95-5:33 m.) above the base of the Gault. The pieces of core 64 MIDDLE ALBIAN STRATIGRAPHY preserved are from 42 feet 6inches, 35 feet, 32 feet 6 inches, 30 feet and 22 feet 6 inches above the base of the Gault and the lithology consists essentially of dark fawn-grey silty clay with shelly fossils. There is no need to emphasise that the cores are very incomplete and that no Subzonal limits can be deduced. Sections in the Gault were formerly exposed in the area of Thame (Oxon) and mentioned by Davies (1899b ; 160). The only information about the zonal strati- graphy is the comment by Spath that at Priestend (SP 691055) the lower Gault, which was exposed for at least 40 feet (12-16 m.), contained plentiful impressions of ammonites of the dentatus Zone often of unusually large size (1943 ; 746). (iv) THAME TO LEIGHTON BUZZARD (BEDFORDSHIRE) The published information on the stratigraphy of the Gault between Thame and Leighton Buzzard, a distance of about 19 miles is again not particularly satisfactory. This is due mainly to the paucity of good exposures and, to a certain extent, to the controversies which have tended to colour the accounts. Itis apparent that deposits of Middle Albian age are present throughout the area, although they are greatly reduced in thickness in comparison with the alleged sequence at Thame. The Gault rests in this area either upon the Kimmeridge Clay, Portland, Purbeck, or Lower Greensand deposits. (a) Long Crendon (Bucks.) No section in the Gault now exists at Long Crendon, which is situated about 24 miles towards the NW. of Thame, but sections in this outlier were described by Jukes- Browne (1900 ; 277), Davies (1899a ; 22), Lamplugh (1922 ; 40-44), and Kitchin & Pringle (1922 ; 164-5). The sequence has also been discussed by Kitchin & Pringle (Ig21a ; 62 : 1922 ; 284-5), Spath (1943 ; 746) and Casey (1961a ; 569). Kitchin & Pringle (Ig21a ; 62 : 1g2Ib ; 174 see also Spath 1943 ; 746) considered that the Upper Gault rested directly upon Purbeck Beds here but the detailed evidence to sub- stantiate this conclusion was not given. On three counts it appears certain that Lower Gault is present. It is important to note that Davies (1899a ; 22 : 1899b ; 161) recorded I. concentricus from the 8 feet of Gault then exposed, but no ammonites were discovered and, therefore, the exact age still remains uncertain. In the main outcrop to the S., the lower part of the Upper Albian is quite fossiliferous with orbignyi Subzone ammonites and the ubiquit- ous Inoceramus sulcatus. Also Lamplugh (1922 ; 40-44) demonstrated that a thin development of Shenley Limestone was present below the Gault (see also Casey 1961a ; 569). It seems probable, therefore, that Davies’ record of I. concentricus is correct, that these clays are of Middle Albian age, and that there is no overlap of Upper Gault in this area as Kitchin & Pringle held. (b) Haddenham (Bucks) Although no section exists in the main outcrop between Thame and Aylesbury, two ammonites are preserved in the Buckinghamshire Country Museum, Aylesbury, IN THE ANGLO-PARIS BASIN 65 which are labelled Haddenham. Although the circumstantial evidence indicates that this is the Buckinghamshire Haddenham, this locality is not on the Gault whereas the Cambridgeshire locality is. With this reservation in mind these ammonites (W. J. Welford Colln., accession No. 176-24) are here identified as Euhoplites aff. meandrinus and Dimorphoplites aff. niobe (the late mutation known from the upper nodule bed of Bed IV at Folkestone). Both are preserved as incomplete blackish phosphatic casts without the shell, and indicate a distinct nodule bed or clays with scattered nodules of late lovicatus Zone age within the Gault of this area. Davies (1899a ; 55-56) disputes that the Gault was exploited S. of Haddenham Low situated about 14 miles NE. of Haddenham (See also Balance 1964 ; Map 2). The main outcrop, however, is at no great distance to the E. of Haddenham. No information has been published about Middle Albian sediments in the 6 mile tract of country between Haddenham and Aylesbury, although Balance (1964 ; 396) has reported the Lower Gault to be present throughout the area. (c) Aylesbury (Bucks) The basal part of the Gault was formerly exposed in the Walton Cutting on the Metropolitan railway line (L.T.E.). The cutting extends SSE. from the bridge (SP 823130) carrying the B 4443 (Stoke Road) over the railway line, Walton, Aylesbury. It was described by Pringle & Chatwin (im Sherlock 1922 ; 9) who reported that the basal bed of the Gault rests directly upon the Portland Beds. No Bed Lithology Ft Ins M Fi Mottled fawn shelly clay marked by a shell seam at the 3 base with part phosphatised fossils. < 4 10 3 a a) | 2 Dark grey shelly clay with scattered phosphatic nodules 2 2 north becoming glauconitic and gritty downwards In basal 10 inches | to the sediment has become very glauconitic and gritty in current | 3 6south swirls of glauconite sand. “. a5. | Scattered black septarian phosphatic nodules in glauconitic clay. wy enLoms eulatiel = aac v rae | Weathered grey glauconitic clay, l BN ele 4-5 | 3 | whitish phosphatic nodules with a few black septarian phosphates — Bre gee te 2-3 Ee Glauconitic gritty loam brownish in basal 1foot with SERIE! 3 2 0 brown phosphatic nodules. \z S| at | Ferruginous yellow gritty clay resting on guttered surface of:- | e! |= 7 a Portland Beds Fic. 28. Section exposed in trench dug by Messrs S. A. Leach & Co. along the field bound- ary extending for about 150 yds from SP 8235012425 to SP 8245012333, approximately midway between the B 4443 Stoke Mandeville road and the L.T.E. Metropolitan railway line from Aylesbury to Stoke Mandeville, Aylesbury, Buckinghamshire. E 66 MIDDLE ALBIAN STRATIGRAPHY fossils were found, and indeed, the only fossils recorded from the lower part of the Gault in this area were obtained from a nodule bed stated to occur at about 10 feet (3:04 m.) above the base of the formation (Pringle & Chatwin im Sherlock 1922 ; 9). This bed has yielded an upper Albian fauna (Jukes-Browne 1900 ; 278 whose inclusion of this horizon in the Lower Gault was an error : C. W., & E. V. Wright 1939 ; 115- 116 : Spath 1943 ; 746). Kitchin & Pringle took this fact to confirm an extreme conclusion, stating that the Lower Gault had been overstepped by the Upper Gault in this area (1922 ; 164-5). Pringle & Chatwin (7m Sherlock 1922 ; 8) were more objective in that they pointed out that there was no evidence at that time for the presence of the Lower Gault. Spath (1943 ; 746) although vague was a little more cautious. Important new information, demonstrating the presence of the spathi Subzone in the lower beds of the Gault, was obtained by the writer from a trench dug by Messrs. S. A. Leach & Co., during the laying of sewer pipes in January 1967. This very temporary section was situated only a few hundred yards S. of the Walton Cutting and the sequence is shown graphically in text-fig. 28. No fossils were obtained from Beds I-5 and their exact age is uncertain. Bed 6 yielded a small bivalve fauna consisting mainly of a small Ostvea and a few specimens of Nucula together with a single example of Neohibolites minimus. The shell seam at the base of bed 7 contains numerous Inoceramus concentricus and some partly- phosphatised Hoplites (H.) with simple dentatus ribbing, all with the nacreous shell. The species include H. (H.) dentatus and H. (H.) cf. maritimus some being quite large —6 to 8 inches in diameter, and the specimens of J. concentricus are also of large size. A few specimens of Dentalium and Nucula also occur. This same faunal assemblage occurs in the remainder of Bed 7 but it is crushed flat. The ammonites indicate the lower part of the spathi Subzone, and it is unfortunate that no higher levels were exposed at this locality. Another ‘ cut and fill’ trench exposing higher beds was excavated in February 1967 in the area approximately 1475 yds a little S. of E. of the trench described above. This trench was dug to a depth of 6 feet and extended from a point about 600 yds NNE. of Stoke Grange to a point about 400 yds. ENE. of Stoke Grange (SP 8357512340 to SP 83801190), to the NE. of the A 413 (Wendover Road), Ayles- bury. The trench was apparently cut in the direction of strike and exposed weathered dark blue-grey clay with small buffish phosphatic nodules and patches. No determinable fossils were found except at the field boundary (SP 83621225) where two very badly preserved fragments of ammonites were seen. One was comparable to Dimorphoplites, the other an equally poor fragment of Euhoplites. Together they suggest an horizon below that exposed in the trenches along the A 41 in the Aston Clinton area described by Wright & Wright (1939) which at certain points yielded an orbignyt Subzone fauna. There is no doubt that the thickness of sediments below the orbignyi Subzone nodule bed in the Aylesbury area exceeds Io feet (3-04 m.) and it is likely that there is a good deal more. IN THE ANGLO-PARIS BASIN 67 LITTLEWORTH 5 AYLESBURY 15 BILLINGTON CROSSING SOUTHCOTT spathi eodentatus condensed floridum, kitchini & regularis regularis Woburn Sands Portland Kimmeridge Beds Clay Fic. 29. Correlation of sections between Aylesbury and Leighton Buzzard. 68 MIDDLE ALBIAN STRATIGRAPHY (d) Aylesbury to Leighton Buzzard (Beds.) At the outcrop between Aylesbury and Leighton Buzzard, a distance of about 10 miles, there is very little information about the stratigraphy of the Gault except for borehole records e.g. Jukes-Browne (1900). A brickyard at Littleworth (SP 881233), Wing, Buckinghamshire, described by Jukes-Browne (1900 ; 278), Davies (Igor ; 140, 1915 ; 92) and Lamplugh (1922 ; 89-90), is now badly degraded, Lamplugh (1922 ; 40) records Inoceramus concentricus from the ‘10 to 15 feet of shattery dark-blue Gault . . . ’ which was estimated to lie at about 10-12 feet (3:04-3:65 m.) above the Gault basement bed. Specimens from the Lamplugh Collection are preserved in the British Museum (Nat. Hist.) (BMNH L 59863-8) and indicate that these sediments are of Middle Albian age. There is, therefore, over 27 feet (8-22 m.) of Middle Albian sediments in this area resting upon a thin development of Shenley Limestone which in turn rests upon Kimmeridge Clay. It is significant that Neo- hibolites minimus is apparently plentiful here, in contrast to the Aylesbury area. In the short distance (14 miles) between Littleworth and Southcott, Buckingham- shire (SP 90052452), the Woburn (or Leighton) Sands intervenes below a similar development of Shenley Limestone (Lamplugh 1922 ; 38). Moreover, the Shenley Limestone lenticle forms the base of a 2 to 3 foot bed of loam with phosphatic nodules below the Gault. These phosphatic nodule beds form an important feature at the base of the Gault at Leighton Buzzard, Bedfordshire, where they are essentially of late tardefurcata and early mammullatum Zone age, with the eodentatus Subzone of the Middle Albian at the top. The equivalent of the Lower Gault represents the spathi, intermedius, and niobe Subzones. A description of the Albian sediments in the Leighton Buzzard area is to be presented elsewhere, and at a later date, an account of the Middle and Upper Albian sediments of East Anglia will also be given. This region flanking the London platform and the North Sea area, although of considerable stratigraphical interest, does not contribute any fundamentally new knowledge to the ammonite zonal sequence of the Anglo-Paris Basin, the stabilization of which is the main purpose of this paper. E. Borehole Evidence There are now a great number of deep boreholes in southern and eastern England drilled principally in the search for water, oil and gas, and in Kent, for coal. To this number can be added a few purely exploratory borings. These have provided a good picture of the post Tertiary configuration of the Palaeozoic surface, and of the strati- graphy of the Mesozoic sediments which have buried it (e.g. Kent 1949, Falcon & Kent 1960). It is now apparent that Albian sediments underlie the Chalk through- out the area covered by that formation in England. In this work, the Wessex basin, and the area of the London Basin, Essex, and East Kent only will be considered. Borings in these areas have yielded important new information, including strong indications of post Jurassic to basal Upper Albian faulting along part of the Thames axes, certainly E. of London (Owen, in press). IN THE ANGLO-PARIS BASIN 69 (i) HAMPSHIRE BASIN (a) Winchester District The only borings through the Gault which have yielded information of zonal value are situated in the Winchester area and were drilled for the Gas Council by the British Petroleum Co. Winchester No. r Chilcomb, Hants. (SU 50172830) The division between the Upper Greensand and Gault is taken at a depth of 310 feet (94.48 m.) and the Gault is 250 feet (76-2 m.) thick. Coring was not con- tinuous and neither the thickness of Upper Albian sediments nor the exact Subzonal boundaries in the Middle Albian sediments could be determined. Nonetheless, the fragments of core show that between 426 feet 6 inches and 438 feet (128-16 m.— 133°50 m.) the essentially dark-grey silty and shelly micaceous clays contain Inoceramus sulcatus indicating a lower Upper Albian age (cristatum or orbignyi Sub- zones). There is then a gap of 41 feet (12-49 m.) in cored samples. At 479 feet (146 m.) depth, the mid-grey shelly silty micaceous clays are of Middle Albian, intermedius Subzone age, and the sequence contains Anahoplites of the intermedius group to a depth of 490 feet 2 inches (149-40 m.), a level 69 feet 10 inches (21-28 m.) above the base of the Gault. The spathi Subzone with crushed Hoblites (H.) spp. is certainly present at a depth of 501 feet 1 inch (152-73 m.), and the sedi- ments from this level to a depth of at least 513 feet 3 inches (156-43 m.) consist of alternating fawn and mid-grey, silty micaceous shelly clay bands. At 521 feet (158-80 m.) the nacreous shells are found to be completely replaced by pyritic films, and this pyritic facies is a feature of the sequence down to the base of the Gault at 560 feet (160-68 m.). Crushed Hoflites (H.) spp., are present in the predominantly fawn-grey silty micaceous clay of the lower part of the Gault to a depth of 526 feet (160-32 m.) but no ammonites have been found in the remaining 34 feet (10-36 m.). The basal 5 feet (1-52 m.) of the Gault is very pebbly, becoming a pebbly loam at 559 feet (170-38 m.) depth. The Lower greensand underlies the Gault. Winchester No. 4 Itchen Valley, Hants. (SU 51133007) This boring produced only poor chip and core returns during its traverse of the Gault. Hoplites (H.) sp. with dentatus ribbing was found at 11 feet 6 inches (3-50 m.) above the base of the Gault, at a depth of 1258 feet 6 inches (383-43 m.). This was preserved in an identical manner and lithology to that seen at the same level in Winchester No. r. Winchester No. 5 Twyford, Hants. (SU 50252712) Only a few cored samples were recovered from the chipped sequence. At a depth of 963 feet 8 inches (293-52 m.) only 7 feet 4 inches (2-235 m.) above the base of the Gault, a crushed heteromorph ammonite with indications of lateral spines was found. This is almost certainly a Protanisoceras (P.) and indicates the lyelli Subzone. 70 MIDDLE ALBIAN STRATIGRAPHY (b) Relationship of Winchester to Portsdown, the Weald, and the Isle of Wight The correlation of the Gault sequence in the Winchester No. 1 boring with those of Selborne, Nyewood, and Compton Bay, is shown as far as is possible in text-fig. 30. The lithological succession shown by the Winchester borings is comparable to that of the outcrop at Selborne on the western border of the Weald. They both show in the spathi Subzone sediments a lower pyritic facies overlain by clays in which the shells are preserved and in which a good benthos is present (Owen 1963a ; 43-44). More- over, at Bradshott Hall clays of basal Upper Albian age were seen by Osborne-White (IgIO ; 20) to overlie clays classified with the ‘ interruptus Zone’ in Jukes-Browne’s sense. The lower clays could be of intermedius Subzone age (Owen 1963a ; 51). From the map given in text-fig. 18, it is apparent that the borings at Winchester and Portsdown, and the natural exposure at Culver Cliff in the Isle of Wight all lie roughly on the same NNW-SSE. line. The total thickness of the Gault at Win- chester No. I is 250 feet (76-2 m.) compared with 163 feet (49:68 m.) at Portsdown situated 15 miles to the SSE., and just over 100 feet (30-4 m.) at Culver Cliff. No information on the degree of ammonite subzonal representation in the chipped sequence of the British Petroleum Portsdown boring in known (Taitt & Kent 1958), but, in Hampshire, West Sussex, and in the Isle of Wight, there is a similar change in facies within the spathti Subzone from pyritic clays below to shelly clays above. Superficially it seems that as one proceeds SSE. from Winchester the decreasing thickness of the sediments suggests the shallowing of a basin in this direction. How- ever, at Winchester the lower part of the Upper Albian is represented by at least 128 feet (39-01 m.) of silty Gault, more than the total thickness of the Gault at Culver Cliff in which the lower part of the Upper Albian is also represented (p. 43). The decrease in thickness of Middle Albian sediments from Winchester to Culver Cliff is, therefore, not particularly well marked. It is also apparent that the detailed lithological sequence in the spathi Subzone sediments which is recognisable for a distance of over 35 miles at the outcrop in the south western part of the Weald is totally different from that of the Isle of Wight (text-fig. 30). The common distri- bution of the pyritic facies reflects the presence of a common sea environment which affected different depositional areas, and it is apparent from the pre-Albian sequence at Portsdown that this area formed a ridge separating the area of the south western Weald from that of the Isle of Wight. The Lower Greensand in the south-western area of the Weald thins rapidly towards Portsdown (Falcon & Kent 1960). Continuing SW. into the Isle of Wight the Lower Greensand as a whole thickens from Redcliff NE. of Sandown to reach a known maximum in the southern part of the Island and this increase in thickness can be correlated with an increase in finer grade sediments. It is apparent from the dis- tribution of lyell1 and spathi Subzone sediments that the Portsdown ridge affected Middle Albian sedimentation. By Middle Albian times this submarine feature con- sisted of an elongated swell (text-fig. 52), and its extent can be determined by the presence of the ‘Iron Grit’ beneath the Gault and the absence of tardefurcata and mammillatum Zone phosphatic nodule beds. The Lyelli Subzone sediments are IN THE ANGLO-PARIS BASIN COMPTON WINCHESTER SELBORNE NYEWOOD BAY NO. 1 Ft intermedius Subzonal correlation lines —— ——Lithological correlation lines Provisional comparison of the Winchester No. 1 boring with the outcrop to the south and east. 72 MIDDLE ALBIAN STRATIGRAPHY probably present at Winchester, and may well be present in the unexposed lowest part of the Gault at Selborne in the western Weald in view of the close similarity which exists in the detailed lithological sequence between this locality and the Horton Clay pit, Upper Beeding (text-fig. 14). Sediments of this Subzone are known to intervene between the ‘ Iron Grit’ and the spathi Subzone sediments along the out- crop between Nyewood and Storrington, but they are thin and gritty (p. 34). Inthe southern part of the Isle of Wight, however, sediments of this age are again compar- atively well developed. The spathi Subzone sequence recognised at Selborne thins southwards to Nyewood but lithologically it remains the same (Owen 1963a & text- fig. 30). In the Isle of Wight, however, the sediment sequence is quite different. In the absence of sections it is not possible at this time to determine whether the Ports- down swell affected deposition during later Middle Albian Subzones. It is becoming apparent that the thinning of the Lower Greensand and the Gault at Compton Bay relates to yet another ‘swell’, probably that indicated by the Ringwood gravity high, evidence of which is provided by the British Petroleum Co., borings at Fordingbridge, Hants (Falcon & Kent 1960 ; 48-49), and Bere Regis, Dorset (Falcon & Kent 1960 ; 7), in which the Gault was found to rest directly upon the Kimmeridge and Oxford Clays respectively. (i) LONDON BASIN, EAST ANGLIA, AND KENT (a) London Basin, S. Essex & N. Kent Borings north of the Thames at Canvey Island (Smart, Sabine & Bullerwell e ai., 1964) Fobbing (Dewey eé al., 1925) Beckton Gasworks No. 4 (Barrow & Wills 1973), Essex ; Tottenham Court Road (Prestwich 1878, Judd 1884), Willesden No. 1 (Falcon & Kent 1960 ; 15), London ; and Bushey, Hertfordshire, provide evidence that the Upper Gault rests directly upon either the Palaeozoic rocks of the Mesozoic floor or upon a thin development of Jurassic or Lower Greensand sediments. However, in the Gas Council Cliffe group of borings encompassing the area of the East Tilbury Marshes, Essex, and across the Thames in the Cliffe and Higham parishes of Kent, Middle Albian sediments are represented in a sequence closely comparable to that seen in the Lower Gault of the Maidstone By-Pass (p. 18), and, moreover, they show no sign of either a land area or submarine cliff only a few miles to the north. The Lower Gault of the Cliffe group of borings rests upon a thin development of Lower Greensand which in turn rests upon Oxford Clay preserved in a late Jurassic- early Cretaceous graben structure, or in the case of the two most southerly borings upon Devonian sediments as at Canvey Island and Fobbing situated to the north of the graben. The stratigraphy of these borings, the structure of the area, and its tectonic history, are discussed more fully elsewhere (Owen in press). In this work it is concluded that the absence of Lower Gault over much of the area north of the Thames in London and South Essex, is due to a further movement of the northern fault of this graben in early Upper Albian times. Further west in northern Surrey, three borings have yielded information about Middle Albian sediments. These are located at Addington, Richmond and Egham IN THE ANGLO-PARIS BASIN 73 (Virginia Water), but the information is very incomplete, and in the case of the last boring mentioned it is highly suspect. The location of the borings is shown in text-fig. I. Addington The boring at the Croydon Waterworks, Addington Pumping Station on the E. side of Featherbed Lane (TQ 371628) yielded a core, parts of which are preserved in the Institute of Geological Sciences. The Upper Gault-Lower Gault junction con- sists of a phosphatic nodule bed with cristatwm Subzone fossils and was reached at about 879 feet (267-91 m.) depth. This is underlain by grey shelly clay represented by fragments of core from between 880 and 882 feet (268-22—268-83 m.) and which yield Inoceramus concentricus and poorly preserved ammonites which could indicate either a loricatus or lautus Zone age. No further core fragments have survived from the remainder of the Lower Gault sequence which has a total thickness of 22 feet (6-70 m.). This boring is situated 9} miles WNW. of the section at Dunton Green at the outcrop (p. 26) and indicates that the thin development of Lower Gault there continues along the WNW. direction. Richmond The boring at the old Richmond Vestry Waterworks, Water Lane, Richmond (TQ 17657470) was first described by Judd and Homersham (in Judd 1884) and subsequently by Whitaker (1889 ; 214-217). Spath (1926a ; I51, 1930a ; 294) demonstrated the presence of the Ewhoplites inornatus band at the base of the orbignyz Subzone (Upper Gault) and that the Lower Gault is also present. The Gault core was stored in the British Museum (Nat. Hist.) for many years before being transferred to the Institute of Geological Sciences and is, unfortunately, in a dirty state. J. sulcatus is still present at a depth of 1116 feet (340-15 m.), and by I11g feet (341-07 m.) J. concentricus is present. The Upper Gault-Lower Gault junction occurs, therefore, between these two depths. The base of the Gault was located at a depth of 1139 feet 6 inches (347-16 m.) and so the Lower Gault is between 20 feet 6 inches (6:25 m.) and 23 feet 6 inches (7:16 m.) thick. No subzonally diagnostic ammonites are present in the Lower Gault core. The base of the Gault rests upon I0 feet (3:04 m.) of sediments tentatively classified with the Lower Green- sand which in turn rests upon Jurassic sediments. In the Griffin Brewery boring at The Mall, Chiswick, 34 miles to the NE. of the Richmond boring, the Gault rests directly upon Devonian sediments of the London Platform. The age of the base of the Gault at Chiswick is, however, unknown. Egham (Virginia Water) This boring situated at the Holloway Sanatorium, Egham (TQ 002685), was described by Dewey (im Dewey e¢ al., 1925 ; 128). He records a band crowded with I. sulcatus between depths of 1358-1360 feet (415-9I-414:52m.) some 67 feet (20-42 m.) above the base of the Gault. From the basal nodule beds, Templeman collected ammonites which led Chatwin to conclude (im Dewey e¢ al., 1925 ; 130, 132) that the base of the Gault was of Upper Gault age providing another example of overlap. 74 MIDDLE ALBIAN STRATIGRAPHY Now, Inoceramus sulcatus is characteristic of and restricted to the orbignyi and cristatum Subzones and yet the ammonites recorded from the nodule bed at 1424 feet (434:03 m.) depth include material of varicosum Subzone age. A re-examination of the material stated to have come from this nodule bed shows that it includes ammonites from various Upper Gault horizons. The specimen of Prohysteroceras (GSM. AT 3787) is indeed correctly identified. It is, however, a form of the varicosum Subzone preserved in an identical manner to those of the basal varicosum nodule bed in the Leighton Buzzard area indicating a southerly extension of that bed. As it was found below the lowest recorded occurrence of I. sulcatus at 1400 feet (426-72 m.) depth, the only possible explanation is that it must have fallen from the side of the hole together with the other phosphatic fragments during the collapse of the hole reported by Dewey (in Treacher & Dewey 1925 ; 450). Material acquired later from Templeman is preserved in the Palaeontology Depart- ment of the Institute of Geological Sciences and shows that the Lower Gault under- lain by mammuillatum Zone sediments was in fact traversed by this boring. These specimens, unfortunately, have no depth measurements recorded against them, but include Euhoplites cf. opalinus (GSM. AT 4800) indicating the lautus Zone ; Euhoplites of the meandrinus group (GSM. AT 4799) indicating the upper part of the loricatus Zone ; and spathit Subzone Hoplites (H.) spp. (GSM. AT 4801-4) preserved in pebbly gritty greyish phosphate. Unfortunately, this boring is now stratigraphically suspect, but if one disregards the so-called phosphatic nodule bed at 1424 feet depth then it is possible to reinterpret the lower part of the hole. The last record of Inoceramus sulcatus was at 1400 feet (426-72 m.) depth about 27 feet (8-23 m.) above the base of the Gault. This figure of 27 feet is not an unreasonable one for the Lower Gault when one considers the geographical position of the boring. The highest record of J. sulcatus is at 1358 feet (413°9I m.) boring depth which indicates that the combined thickness of the cristatum and orbignyt Subzone sediments is at least 42 feet (12-80 m.) thick. This is a thick, but not impossibly thick, sequence. (b) The area of the Kent Coalfield Despite the large number of borings and various colliery shafts which penetrated through the Gault in the search for Coal Measures in Kent, only a small fraction has yielded information on the stratigraphy of the Gault. Financial costs dictated that boring through the Mesozoic rocks should be as rapid as possible and the sequence was often chipped. However, at the following seven localities shown on text-fig. 31, useful information has come to light and it is apparent that eodentatus and lyelli Subzones sediments are of widespread occurrence. Chislet Colliery In the downcast shaft of the Chislet Colliery situated 3020 yds N. 54° 30’E. of the North Shaft (TR 232657) an exposure of approximately 12 feet (3-65 m.) was seen of Lower Gault resting on the basal conglomerate of mammillatwm Zone age which in turn rests unconformably on Coal Measures (Casey 1961a ; 535). A phosphatised IN THE ANGLO-PARIS BASIN 75 fragment of Hoplites (Isohoplites) sp. (GSM. Ca 1416) was obtained by Dr. R. Casey from 1 foot 6 inches (0-457 m.) above the basal conglomerate indicating the eodentatus Subzone. From 2-4 feet (0-60-1-21 m.) above the conglomerate there occur glau- conitic gritty darkish grey clays with fossils in which the shells have been replaced by pyrite. Ammonites from this bed collected by Dr. Casey include Lyelliceras cf. lyelu (GSM. Ca 1423-4) and Hoplites (H.) spp. including H. (H.) baylet (GSM. Ca 1426), and Beudanticeras cf. albense (GSM. Ca 1431). A specimen of Protanisoceras (P.) cf. barrense (GSM. Ca 1437) preserved in the same manner was picked up from the tip. This assemblage indicates the lyelli Subzone. One specimen (GSM. Zn 2472) is a Hoplites (H.) sp. preserved partly phosphatised in mid-grey shelly clay and is stated to have come from a height of about 12 feet (3:65 m.) above the basal con- glomerate ; it indicates the spathi Subzone. | ? Fa 1D miles fo) 5 10 15km @ Bobbing Chisigt downcast Ebb sfleete Benet Tilmanst one ° Ringwould Guilford ° St Margarets Bay KEY (outcrop) Bi co: DOVER Aycliff © FOLKESTONE pay Fic. 31. Locality map of borings yielding subzonal information in the Kent coalfield. Ebbsfleet Fragments of the core preserved in the Institute of Geological Sciences from this boring, situated 495 yds S. 5°E. of Ebbsfleet House, Eastry (TR 337619), about 7? miles E. of the Chislet Colliery, shows that the Lower Gault was entered at between depths of 977 and 978 feet (297°79-298-I m.) and is about 27 feet thick (8-23 m.) (Lamplugh, Kitchin & Pringle 1923 ; 178). Lovricatus Zone sediments are definitely present at 12 feet 6 inches (3:81 m.) above the base of the Gault (GSM., Pl. 3854), and 76 MIDDLE ALBIAN STRATIGRAPHY at 7 feet 6 inches to 7 feet (2-286 to 2-133 m.) above the base crushed Hoplites (H.) spp., occur with the shell, indicating the spathi Subzone. Lilmanstone The original manuscript accounts of the succession shown in the Shafts Nos. 1, 2 and 3 of the Tilmanstone Colliery are preserved in the Institute of Geological Sciences. The collecting was carried out by Burr and Griffiths. Griffiths, then employed as the Survey fossil collector, knew the stratigraphical value of Inoceramus sulcatus and I. concentricus and it is possible to state with some confidence from the Log that the junction between the Upper and Lower Gault occurs at a depth of 870 feet (265-17 m.) in the No. 1 Shaft (TR 288505) and that the Lower Gault is 62 feet 4 inches (18-99 m.) thick. From the account of the No. 2 Shaft (TR 288504), how- ever, the Lower Gault appears to be only about 52 feet (15:85 m.) thick. The possible explanation of this difference in thickness is provided by the No. 3 Shaft (TR 288505) which showed the Gault to be affected by faulting. Whether this faulting is a posthumous movement of the Tilmanstone Fault which affects the Palaeozoic rocks and earlier Mesozoic rocks is not clear. Nonetheless, it is readily apparent that the Lower Gault at the Tilmanstone Colliery is very thick. Very little material has been preserved from these shafts but one specimen (GSM. Zm 5153) is of considerable interest. It is an early form of Lyelliceras known to occur in the eodentatus Subzone in France, but unfortunately no depth has been recorded against the specimen. It is interesting to note that in No. 2 shaft at a height of 21 feet 8 inches (6-60 m.) from the basal conglomerate a ‘ 3 inch band of Ammonites interruptus ’ was recorded. This might indicate a considerable expansion of the dentatus Zone sediments in this area. Further evidence of this is provided by the material from the Shaft of the old Guilford Colliery (TR 281469) 24 miles SSW. of Tilmanstone. Guilford Colliery The shaft of the Guilford Colliery, situated near the south-western end of Walder- share Park, Coldred (TR 281469) is now disused. Fossils collected from the Gault during the sinking of the shaft are preserved in the Institute of Geological Sciences (presented by the Kent County Education Authority), and in the collection of Brigadier G. Bomford to whom I am particularly indebted for permitting me to examine his material. Unfortunately, the depths indicated for the individual specimens presented by the Kent County Education Authority is suspect. It seems, however, that at about 851 feet (259-38 m.) depth, the /autus Zone nodule bed at the top of the Lower Gault was reached. This contains material of daviest Subzone age as wellas of crvistatum Subzone age, and is, therefore, comparable to the nodule bed at the outcrop to the west. If this depth of 851 feet (259-38 m.) is correct then the Lower Gault is 59 feet (17.98 m.) thick, a little thinner than the No. 1 shaft at Tilmanstone. The only definite information about the Lower Gault here is provided by Brigadier Bomford’s collection made from the tip heap of the shaft. This includes material from a nodule bed of lyelli Subzone age which yielded Lyelliceras lyelli (GB. 5443, 5447, 5446), L. radenaci (Pervinquiere) (GB. 5445), Protanisoceras (P.) buvigniert (GB. IN THE ANGLO-PARIS BASIN 77 5465), together with species of Hoplites (H.) of both the lyelli and spathi Subzones. This dentatus Zone sequence in the central area of the Kent Coalfield thins consider- ably in a south westerly direction towards the outcrop, and there is evidence to suggest that it thins also eastwards towards the Kent coast. Ringwould The Mesozoic rocks traversed by the boring for the National Coal Board made in 1955 and situated 760 yds W. 14°S. of St. Nicholas’s Church, Ringwould (TR 35294812), has been described by Bisson (7m Bisson ef al., 1967 ; 111-114), and fossils from the Gault were identified by Casey. The Upper-Lower Gault junction consists of a phosphatic nodule bed and was met at a depth of 839 feet 4 inches (255-83 m.). The top of the tough phosphatic rock bed of the type seen elsewhere at the base of the Gault was reached at a depth of 876 feet 11 inches (267-28 m.). The Lower Gault, therefore, has thinned to 37 feet 3 inches (11-35 m.) and the basal few inches in fact may well be of mammuillatum Zone age. A re-examination of the fragments of the core preserved in the Institute of Geological Sciences has yielded the following additional information. Crushed Dimorphoplites comparable to D. tethydis Spath non Bayle occur at depths of 842 feet 3 inches (256-71 m.) and 845 feet I inch (257-58 m.) and indicate either the top of the meandrinus Subzone, or the lautus Zone. At 860 feet 5 inches (262-25 m.), a specimen of Hamites tenwicostatus together with a juvenile ?Dimorphoplites niobe at 862 feet 2 inches (262-79 m.) suggest the presence of the mzobe Subzone. The intermedius Subzone is certainly represented at 866 feet 8 inches (264-16 m.) and 867 feet g inches (264-49 m.) by crushed examples of Anahoplites intermedius. The presence of the spatii Subzone is indicated by crushed specimens of Hoplites (H.) at 871 feet 11 inches (265-76 m.) to 872 feet I inch (265-82 m.) in dark grey clay. At 873 feet (265-25 m.) the clays become glauconitic, and at 875 feet 10 inches (266-95 m.) they become sandy for the remaining 1 foot I inch (0:33 m.) before the basal rock bed is reached. The sequence in the lower part of the Middle Albian sediments is demonstrably thinner than at Tilmanstone where ‘ dark sandy Gault’ commences some 21 feet (6-4 m.) above the base. An even thinner sequence may be present in the next boring mentioned here. St. Margaret's Bay. The National Coal Board boring at St. Margaret’s Bay situated 1030 yds E. 30°N. of St. Margaret’s Church, St. Margaret’s at Cliffe (TR 36654533), has been described by Bisson and Melville (im Bisson et al., 1967 ; 105-110). The bulk of the sequence was chipped, but at a depth of 800 feet (243-84 m.) cores were taken for 2 feet (0-61 m.), at 830 feet (252-98 m.) a I foot (0-30 m.) core was taken, and a 3 feet 8 inch (I-12 m.) core from 840 feet (256-03 m.) and the base of the Gault at 843 feet 8 inches (25715 m.). The only ammonite recorded was a specimen of a mortoniceratid ammonite, probably Prohysteroceras, said to have come from a depth of 830 feet (252-98 m.). What is probably a portion of the same ammonite is stated to have come from a depth of 830 feet 3 inches (253-05 m.). Casey considers that its position 78 MIDDLE ALBIAN STRATIGRAPHY only 13 feet 8 inches (4-16 m.) above the base of the Gault is anomalous and should not be accepted. However, the portion from 830 feet 3 inches (253-05 m.) is not apparently derived and even if the specimen had come from the core between 800-802 feet (243-84 m.) this still suggests a thinner Lower Gault sequence than at Ringwould. These records need to be verified in any future boring in this area, but the possibility of early Upper Albian faulting here of the type seen in the region of the Thames E. of London should not be excluded (Owen in press). The Gault as a whole on the E. coast of Kent thins considerably northwards. Inthe Segas Deal Gas Works boring (TR 374533) it is 86 feet (26-21 m.) thick and in the Thanet Water Board Well, Margate (TR 365701), it is only 67 feet 6 inches (20°57 m.) thick. Aycliff The increased thickness of the Lower Gault seen in the Tilmanstone and Guilford Collieries is maintained in the Dover area. Lamplugh & Kitchin (1911 ; 8) considered from an examination of the Dover Colliery shafts that this was due to an expansion of the higher beds of the Lower Gault, but the exploratory borings in the Dover area for the Channel Tunnel show in fact that the reverse is the case. There are phosphatic nodule beds in the cristatum Subzone comparable to those at Folkestone within Bed VIII. The Gault in one of these borings, Dover No. 1 (Aycliff) (TR 294395), has been described lithologically by Bisson (in Smart, Bisson & Worssam 1966 ; ror), and the Lower Gault sequence is shown in text-fig. 32. The lautus Zone is indicated in Bed 11 by the presence of a Dimorphoplites sp. of the chloris-biplicatus group, and in another boring by Euhoplites opalinus. It is considerably attenuated in comparison with Beds V-VII at Folkestone. Bed 10 has yielded a crushed Dimorphoplites niobe which might indicate either the meandrinus, subdelaruei, or niobe Subzones. Neither Bed g nor the bulk of Bed 8 yielded any zonally significant ammonites but crushed Falciferella occurs in the lower 6 inches (1-828 m.) of Bed 8 which suggest the zutermedius Subzone or possibly the miobe Subzone. Anahoplites of the intermedius group occur from I foot (0-304 m.) above the base of Bed 7, and in Bed 6, definitely indicating the presence of the intermedius Subzone. No subzonally diagnostic ammonites are known from Beds 5 and 4, but Bed 3 contains phosphatised fragments of H. (H.) persulcatus and H. (H.) of the paronai group. This is the direct equivalent of Bed I (v) at Folkestone, the dentatus nodule bed, classified with the spatht Subzone. It is highly probable that Bed 4 above is the equivalent of Bed I (vi) at Folkestone (p. 12). The particularly interesting feature of the sequence occurs in Bed 2. This bed is classified with the lyelli Subzone, and contains species of Protanisoceras (P.) at only 12 and 15 inches (0:304—0-381 m.) below Bed 3, and species of Hoplites (H.) occur throughout. This sequence bears comparison with the lower part of the Gault in the Guilford, and Chislet Collieries where the lyelli Subzone is also well developed. At Folkestone, the lyelli Subzone is very condensed and is represented within Bed I (iv). Whether the eodentatus Subzone is represented within the higher part of Bed 1 is uncertain in the absence of ammonites but it is highly likely when one considers the development of the lyelli Subzone here. The lower part of Bed 1 is probably equiv- alent to the ‘ Sulphur’ Band at Folkestone. IN THE ANGLO-PARIS BASIN Bed Utho! Ft Ins M. olo No. ad ¢ristatum Subzone eee 2 14 Mid-grey shelly clay with Inoceramus concentricus flautus Light fawn shelly grey clay with dark burrows —— late loricatus Shelly battleship grey clay with small brown phosphatic nodules in the basal 1inch Light fawn tough shelly clay with Falciferella Medium grey shelly clay with crushed Anahoplites intermedius intermedius @ Pie A alee eae See fe S| a» w : o Gritty grey burrowed shelly clay 1 8 6 ae 5 Mid grey shelly clay becoming paler below with scattered pale buff phosphatic clots I ' 5 ' Gritty burrowed greyclay sparsely shelly with = 3 glauconite in lower half & + 2 | 3 | Blackish phosphatic nodules in gritty glauconitic grey clay ) Mid grey fine clay shelly and burrowed. In lowest 2ft = 42 lin clay becomes gritty. In lowest 4ins glauconite . and black phosphatic fragments occur 1 “ > Is 5 1 Grey silty clay with light burrows and phosphatic nodules 3 pa an Fic. 32. Lower Gault sequence in the Dover No. 1 (Aycliff) boring, Kent (TR 294395). 79 8o MIDDLE ALBIAN STRATIGRAPHY These borings in the area of the Kent Coalfield show that the sequence in the Lower Gault expands considerably eastwards from the outcrop between Folkestone and Maidstone. In this trough area the eodentatus and lyelli Subzones are well developed. The whole sequence thins towards the coastal margin of Kent from the Isle of Thanet to St. Margaret’s Bay northeast of Dover. F. Selection of sections in France It is not possible here to describe the Middle Albian stratigraphy of northern and central France in the same detail as the English sections. The French sections require just as long and careful study, and must include temporary sections seldom available on a chance visit and which are thus the prerogative of our colleagues in France. The purpose of this portion of the work is to make a comparison of the English sequence with a representative selection of sections of four regions ; (i) the Boulonnais ; (ii) the outcrop extending from the River Ornain (Meuse) to the River Armance (Yonne) which includes also parts of the Départements of Meuse, Marne, Haute-Marne, Aube and Yonne ; (iti) the Pays de Bray ; and (iv) the Pays de Caux (text-fig. 33). (i) COMPARISON BETWEEN WISSANT & FOLKESTONE The Albian deposits of the Boulonnais describe a narrow outcrop at the foot of the Chalk escarpment extending from the coast at Petit Blanc Nez south-eastwards to Lottinghen and then roughly westwards towards the coast to disappear beneath the dunes at Hardelot Plage. The deposits rest upon Aptian sediments at Wissant, but inland they may rest directly upon Aptian, ‘ Wealden’, Jurassic, and, near Caffiers, on Palaeozoic rocks. The exposures in the shore and in the cliffs between Wissant and Petit Blanc Nez are indicated in text-fig. 34. The Gault of the Wissant area was briefly described by Barrois (1873, 1875, 1878, but particularly 1879 ; 27-28), Price (1879, 1880 ; 34 etc.) and Jukes-Browne (1900 ; 378-381), but it was not until 1938 (a 98-121) that a good detailed description was given by J.-P. & P. Destombes. Barrois had considered that the sequences at Folkestone and Wissant were not comparable in detail, a conclusion with which the present writer agrees. Destombes & Destombes, however, followed Price in consider- ing that the Wissant succession is comparable to that of Folkestone, although reduced in thickness ; a view accepted by Spath (1943 ; 721). P. & P.-J. Destombes have written an emended account of the Wissant sequence (1965 ; 257-260), the lithological accuracy of which can be confirmed by the writer’s own examination of the section. However, their subzonal classification of 1938 and the implied classification of 1965 requires some revision at certain levels as also does the account by Marie (1965 ; 280-284, table 1). In April 1967 the writer observed good clean sections in the Lower Gault both in the cliffs and in the foreshore, and from the study of these the graphical section (text-fig. 35) has been drawn. The primary bed numbers employed are those used by Destombes & Destombes (1965 ; 258), and the correlation with Folkestone is shown in text-fig. 36. ‘St Jouln = rst cauvitic & seville pdeic Héeve O TOURS St Martin. I'Hortien oForgug les Eaux © ROUEN Villars St. Barthélemy © EVREUX O CHATEAUDUN © VENDOME 60 70 80 90 100km . 1 10 20 30 40 50 60 miles © ARRAS ae O CAMBRAI SS r O AVESNES sec Wiis a 2. © AMIENS © BEAUVAIS PARIS JOIGNYO GIEN fe} © SANCERRE © BOURGES © MEZIERES © SEDAN RETHEL ° VOUZIERS OREIMS CHALONS sur MARNE Revigny Pargny s. Saulx & Maurupt Le Gaty_ TROYES Dienville Q ‘Courcelles prés Clérey La Vendue Mignot: Montiéhu & StFlorentin Bois de Perchois “Mont St. Sulpice Garey © CHATILLON sur SEINE & Beaumont © AUXERRE © CLAMECY Fic. 33. Sketch map of the outcrop of Albian sediments in the Paris Basin showing the positions of the sections mentioned in the text. The pecked line represents the approximate margin of Albian sediments buried beneath overlapping Upper Cretaceous sediments. IN THE ANGLO-PARIS BASIN 81 Cap Blanc Nez --- CHANNEL as Bowen “Chal® ~ - a ORS Escalles Fic. 34. Sketch map of the coast between Wissant and Cap Blanc Nez, Pas de Calais (modified from J-P. & P Destombes 1963). F 82 MIDDLE ALBIAN STRATIGRAPHY At the point marked X on the sketch-map (text-fig. 34) a vertical section normally buried within the dune sands showed a sequence from the Argiles d’Ostrea Leymerii (Upper Aptian) up into the lower part of the Lower Gault!. Price (1879, 1880 ; 34) Bed Lithology g Ins M Blackish phosphatic nodules, mainly casts of fossils with portions of the shell ~ 2-4 13 preserved, in shelly grey clay. v 0 (v) Burrowed grey clay, the burrows having pale infillings, $ (iv) Very dark grey clay with a few scattered part-phosphatised fossils 5 with the nacreous shell preserved. A line of scattered phosphatic 7 nodules occurs 2 inches from the base. lii)Part phosphatised fossils in extensively burrowed Clay. = 1 > = 9 (i1)Grey burrowed $shelly clay. = 4 (i) Dark grey shelly clay. fe) [11 | Black angular phosphatic nodules in qrey clay. v 2 10 Darkish grey clay with scattered shells, and with a scactered & 1 line of phosphatic nodules buff in colour. a 8 °o 9 | Grey shelly clay. re 4 3 “ 2 (il) Sparsely shelly well-bedded dark grey clay, 2 fe) — 2 x a3 8 s 1 (i) Glauconitic blocky dark grey clay, with a thin bedded junction p with 8(li) above,and becoming progress ively more < 8 glauconitic downwards. o o 7 Large brown grey phosphatic nodules with abraded upper surtaces, some compound, 6 with smaller black phosphatic nodulesand fragments of fossils,in glauconitic loam, 2 0 puzosianus Fic. 35. Section in Lower Gault in the sea-cliff extending from point X on the sketch map (Fic. 34) up to the old german block-house 0.4 km SW. of Strouanne, Wissant, Pas de Calais. had stated that at Wissant the ‘ Ammonites-mammillaris Zone and the A.-interruptus zone (Bed I) are mixed together, so much so that it is difficult to divide them; but the fossils from the former have the greensand matrix. ’. Now, in Bed 7 in the section mentioned above, a magnificent fauna of puzosianus Subzone age was collected by the writer preserved in exactly the manner described by Price and associated with a spathi Subzone fauna. The large puzosianus Subzone nodules had obviously stood 1 It appears to be the first time this century that this section has beenseen. It was described by Gaudry (1860). Le Hon (1864 ; 14-16), and Barrois (1879). The section examined by Dutertre, in company with Kirkaldy (1938 ; 121-2), was situated in the cliffs near the farm of Saint Pé. I can confirm the accuracy of Barrois’ section from a point about 4ft. (1°21 m.) below the top of the Argiles d’Ostrea Leymerii up to the top of the Sables Vert. IN THE ANGLO-PARIS BASIN 83 up as a hard-ground on the spathi Subzone sea floor for their upper surfaces are strongly eroded (text-fig. 35). The currents had scoured out the sandy matrix from around the nodules, and, subsequently, phosphatic fragments from a later spathi Subzone period of erosion accompanied by a gritty clay sediment were forced into the crevices between and even underneath the nodules of puzosianus age. J.-P. & P. Destombes record ‘ Protohoplites raulinianus ’ from this bed (1938a ; 102). In the foreshore to the NE. up to Strouanne, these puzostanus Subzone phosphatic nodules are still present but are scattered and much more rolled : they have not yielded fossils. In the reef on the foreshore in front of Petit Blanc Nez a few putty- coloured gritty well-rolled smaller phosphatic nodules of puzostzanus Subzone type still occur mixed in with the predominantly spathi Subzone debris. It can be seen, therefore, that the degree of reworking increases north-eastwards from the cliff section near Wissant. In this respect it is important to note that the Palaeozoic floor rises sharply off-shore (J.-P. & P. Destombes 1963 ; 53 text-fig. 3). There is no evidence of the presence of an eodentatus or lyelli Subzone element in Bed 7, and the spathi element is strongly reminiscent of the fauna in Division A in the Maidstone By-Pass (p. 38) which indicates that the earliest part of the spathi Subzone may not be represented either. The equivalent of the Greensand Seam and the basal spatht Subzone element of the dentatus nodule bed at Folkestone is, there- fore, absent at Wissant. It is not easy to make out the complete sequence between Bed 7 and Bed 11 and it is possible that these clays might be somewhat thicker than has been previously recorded. Nonetheless, for the purpose of this account, the general sequence given by P. & J.-P. Destombes will be the one considered. Hoflites (H.) occurs crushed in the matrix of Bed 7 and in the lower 3 inches of Bed 8 (i), and these sediments are classified with the spbatht Subzone. The base of the intermedius Subzone has not been satisfactorily defined but probably commences at the base of 8 (ii). Scattered crushed examples of Anahoplites intermedius & A. praecox occur throughout the bulk of 8 (ii) and P. Destombes records Falciferella in the uppermost 8 inches (20 cms) (1962 ; 196-7). Bed 8 (ii) is, therefore, classified with the intermedius Subzone, however, as can be seen from the section and the general nature of the fauna it differs greatly from the upper part of Bed I and Bed II at Folkestone. P. Destombes (1962) classifies the bed later numbered 9 with the niobe Subzone and this must also include Bed Io. Bed 11 has yielded a remanié fauna of ammonites including Mojsisovicsia sub- delaruet & M. remotum indicating the subdelaruei Subzone, Euhoplites of the mean- drinus group indicating that Subzone, and also fragments of Ewhoplites lautus and E. mitidus indicating the nitidus Subzone. The degree of condensation at Wissant is, therefore, greater than that represented by Bed IV at Folkestone and includes mater- ial also found in the nitidus Subzone sediments of Bed V. The tidus Subzone is well developed in Bed 12 (i-iv) and the preservation of the fossils particularly in 12 (iii) is identical to that of Bed V—VI at Folkestone. It is possible that 12 (iv) may represent the equivalent of the lower part of Bed VII below the base of the daviest Subzone but there is no certain evidence for this. However, it is certain that there is an important break in the sequence between 12 (iv) and (v), 84 MIDDLE ALBIAN STRATIGRAPHY FOLKESTONE M Ft E ZIPS oe SSSeVGii a ic 10 © SINVIIIC) 3 : 30 9 ir) Vil WISSANT Pa 2 8 = 0 ae*. © o*e*/13 25 5 2(v) 42 (iv) ooo 2 (iii) 7 meand, 12 (ii) RE Fe (FC a LR tle 2 ee 42(i) 20 ote Sek feted 1 6 10 IF 7 2 © 9 r c SL Las B(ii) 4 ee 6 oo oe alll (iii) Wii) = Gee Wd) ° B(i) 110) “ 3 E c © © 1 (vii) 7 2 5 1 < ° Qa “ fo) ° eodent Fic. 36. yelli I(ii) Correlation of Lower Gault sections at Folkestone and Wissant. IN THE ANGLO-PARIS BASIN 85 and that the daviest Subzone is absent at Wissant. At the base of Bed 12 (v) Inoceramus concentricus is present but as one works up through the bed it passes through a subsulcatus stage to achieve the form of J. sulcatus just below the cristatum nodule bed 13 (cf. P. & J.-P. Destombes 1965 ; 260). Beudanticeras beudanti also occurs partly crushed with its shell, and it should be borne in mind that d’Orbigny’s holotype of Dipoloceras bouchardianum is from Wissant and is pyritic with the shell ; it almost certainly came from 12 (v). Anahoplites daviesi and its close relatives are absent and in fact the fauna is that which occurs in the lower nodule bed of Bed VIII at Folkestone minus the late davies: Subzone element (p. 15) absent at Wissant. Therefore, the lower part of the cvistatwm Subzone is represented at Wissant by these clays of 12 (v) and this is the only proven section known to the writer where the basal part of the Upper Albian is represented by an uncondensed sequence. Bed 12 (v) certainly does not belong to the daviest Subzone as Marie (1965 ; 279) has indicated. It is worth recording here that Bed 13 at Wissant contains a remanié ammonite fauna which indicates that it represents Bed VIII (ii & iii) at Folkestone together with the clays of Bed IX up to the level at which Hysteroceras orbignyi becomes common. The Euhophites inornatus level, which provides a useful indicator horizon in the lower part of the Upper Albian, is caught up within Bed 13. This bed re- presents, therefore, the bulk of the cristatuwm Subzone together with what has been considered previously to be the lower part of the orbignyi Subzone (see also p. 126). The original account by Barrois (1875a) of the succession between the Wissant area of the Boulonnais and the Département of the Meuse has had very little added to it. This area includes the Ardennes where Barrois demonstrated the major stratigraphic break which exists between the spathi Subzone and the sediments of Upper Albian age classified by him with his ‘ Zone of Ammonites inflatus ’ which he included in the Cenomanian. The sequence in the dentatus Zone is itself incomplete, reflecting the proximity of the area to the Variscan massifs to theeast. Inthe Département of the Meuse, the Middle Albian sediments begin to thicken and it is at Revigny-sur-Ornain that the more detailed account of the sequence in the southern part of the Paris Basin commences. (i) THE OUTCROP FROM THE RIVER ORNAIN (MEUSE) TO THE RIVER ARMANCE (YONNE) The outcrop of the Albian sediments in the southern part of the Paris Basin is shown in text-fig. 33. This strip of country is the classic area for the study of the French Albian ; the name Albian stems from the Roman province of Alba, now the Département of the Aube. It includes the portions of the Départements of the Meuse, Marne, Haute Marne, Aube and Yonne, divided into the old regions of the Argonne (part), then Perthois, and part of the Puisaye. The succession and its facies changes at the outcrop can be demonstrated by brief descriptions of the follow- ing seven sections (a) Revigny-sur-Ornain (Meuse) ; (b) Pargny-sur-Saulx (Marne) ; (c) Les Cétes-Noires prés de Moéslain (Haute-Marne) ; (d) Courcelles prés Clérey (Aube) ; (e) La Vendue Mignot (Aube) ; (f) St. Florentin area (Yonne). These sections demonstrate the important development of the dentatus Zone and 86 MIDDLE ALBIAN STRATIGRAPHY in particular of the eodentatus and lyelli Subzones in this area. The clay facies of the dentatus Zone passes rapidly in the St. Florentin area to a predominately sandy facies characteristic of the succession in the Puisaye-Yonne, Niévre, Cher, indicating the proximity of the Variscan massif of Morvan. In the whole area under consideration the proved sediments of lovicatus Zone age represent only the intermedius Subzone and in the Puisaye these are largely remanié. Sediments of lautus Zone age have not yet been detected. This area has been studied by many French Cretaceous workers. One of the earliest papers written was by Michelin (1838) on the sequence at Gaty, prés Geraudot (Aube). Leymerie (1841, 1842) then described the Gault in the Aube but, unfortun- ately, d’Orbigny (1841) just antedated Leymerie’s description of Ammonites lyelli one of the most characteristic fossils. This was followed by a similar description of the Gault in the Département of the Meuse by Buvignier (1852). Various papers on individual localities were then published but the next important work before Barrois was that of Ebray (1863) who attempted to coordinate the sequence in the various Départements. Barrois made the first attempt to tie in the apparently different sequences of the Boulonnais, Ardennes, and the strip of country from the Meuse to the Niévre (1875). Unfortunately, two very inaccurate attempts were made to correlate the succession in the Aube with that of Folkestone (Price & Delatour in Price 1879 ; 1880 ; 37-40, Jukes-Browne 1900 ; 388-390). The result completely obliterated Barrois’s work in English minds, and eventually led to a great deal of uncertainty as to the strati- graphical position of the clays containing Ammonites lyelli in relation to the sequence known in England. This uncertainty was not completely settled even by Spath (e.g. 1926b ; 1943, 722). It was not until Wright & Wright demonstrated the occurrence of Lyelliceras in the ‘ benettianus’ Subzone in Surrey (1948), and the stratigraphical position more definitely indicated by Casey (1961a) that the question was put beyond doubt in English minds. The first general account of the Albian in this area of France to appear after Barrois was a paper by Lemoine (1910). Larcher (1937) subsequently produced a very interesting paper in which the fauna of the broad lithological units were listed accurately for the first time. However, it was not until 1965 that a more detailed picture of the sequence and its facies changes could be obtained. Four very im- portant papers were presented to the Colloque sur le Crétacé inférieur held in Lyon in 1963. These were published in 1965 and written by :— Larcher, Rat, & Malapris ; P. & J.-P. Destombes ; Marie ; and Ciry, Rat, Malapris & Nicolas. Of these, the paper by P. & J.-P. Destombes is of paramount importance. Recently, Lauverjat (1969) has described the broad lithological sequence and facies changes shown by deep borings through the Chalk along two lines, parallel to the Albian sediment out- crop, from the area of Troyes (Aube) south west to the river Loing (Yonne). (a) Revigny-sur-Ornain (Meuse) Barrois demonstrated (1878), that in the northern part of the Argonne (part of the Départements of the Ardennes, Meuse, and Marne) sediments now included in the IN THE ANGLO-PARIS BASIN Div. Lithology 22 Ww Rather fawn blocky marly clay somewhat ferruginous; > shelly with numerous /noceramus concentricus. The clay mH passes near the base into soft maristone. = S = 15 (ill) Blocky dark fawn grey shelly clay in lower part becoming more massive bedded upwards-—the fossils losing the shell until near the top where shells are preserved again. 10 (il) Phosphatic nodules and part-phosphatised and pyritic fossils In fawn grey slity clay. x ~ x a wn (1) Fawn grey slightly silty shelly clay, weathering to a reddish colour, with scattered pyritic ammonites. ° Fic. 37. Section in Gault at the claypit of the Société B.H.T.P. on the SE. side of the Marne-Rhine canal, about 2 km S. of the centre of Revigny-sur-Ornain, Meuse. 87 88 MIDDLE ALBIAN STRATIGRAPHY Middle Albian appear and thicken southwards. Deposits of lyelli Subzone age, although no longer exposed, are present in this area. Buvignier (1852 ; 525-6 & pl. explanation p. 45) lists lyelli Subzone fossils from as far N. as Clermont-en- Argonne, 31 kms NNE. of Revigny-sur-Ornain. These include Pseudhelicoceras argonnenis (type locality), Brancoceras versicostatum and Lyelliceras lyelli (although he states on p. 521 that the only locality at which this species had been found was at Senard about 17 kms a little E. of N. of Revigny-sur-Ornain). From Revigny- sur-Ornain itself, and, in the case of the last-named species below, between here and Mussey (presumably from the excavation for the Marne-Rhine Canal) he records Nucula bivirgata, Protanisoceras (P.) alternotuberculatum, P. (P.) moreanum (type locality), P. (P.) nodoneum (type locality) and P. (P.) barrense (type locality). Approximately 2 kms S. of the centre of Revigny-sur-Ornain, and to the SE. of the N 395, the Société B.H.T.P. have a large brick and tile works with an extensive clay pit on the SE. side of the Marne-Rhine canal. The pit is worked in two stages by multi-bucket excavators and a sketch section is given in text-fig. 37. Deposition of sediment here was apparently fairly constant and there is an almost perfect transition from the lithology seen at the base to that seen at the top. The only sign of slight condensation occurs approximately 30 feet (9:14 m.) above the base of the section where part-phosphatised and pyritic fossils are more common. The fossils are essentially crushed flat, and at the base of the sequence the ammon- ites consist of Hoplites (H.) spp. including H. (H.) dentatus and Metahamites sabliert (d’Orbigny) indicating the spatht Subzone. A higher spatht Subzone fauna ranges up into the top few feet of Division I, and the band of phosphatised and pyritised fossils about 30 feet (9:14 m.) from the base has yielded ammonites including H. (H.) aff. dorsetensis Spath, H. (H.) pretethydis Spath, and H. (H.) canavariformis com- parable to those found in the upper part of the spathi Subzone in the Weald. Anahoplites praecox and A. intermedius appear at the base of Division 2 and range up through the remainder of the measured sequence. In Dr. P. Destombes’ collection there is a single example of the sulcate form of A. praecox which indicates the lower part of the intermedius Subzone and was probably derived from the top few feet of Division I. The spathi Subzone is represented in this section, therefore, by about 50 feet (15:24 m.) of sediments, and the base of the Subzone has not yet been reached. The top of the intermedius Subzone has not been reached either, and the exposed portion of sediments belonging to this Subzone is about 15 feet (4:57 m.) thick. (b) Pargny-sur-Saulx (Marne) In the area of Pargny-sur-Saulx and Maurupt, situated approximately 12 kms SW. of the section at Revigny-sur-Ornain, there is an important centre of brick and tile production. Houdard (1940 ; 625-636) has recorded the distribution of the fauna collected from the Gault (Argiles Tégulines) in this area but there are no details of the sections. From his lists it is apparent that the lyelli and spathi Subzones are definitely present, and probably the intermedius Subzones as at Revigny. His record of ‘ Acanthoceras’ camatteanum and ‘ Parahoplites’ steinmanni from Pargny suggested IN THE ANGLO-PARIS BASIN 89 that the eodentatus Subzone might also be present. The section between Pargny-sur- Saulx and Maurupt described below provides new information on the basal part of the Middle Albian in this area. The extensive clay pit belonging to the brick and tile works of the Hugenot Freres, situated a few hundred yards E. of the D6o1, 1km NNW. of Maurupt, has been deepened and shows the lithological sequence given in text-fig. 38. Bed 1 did not yield ammonites to the writer but bivalves are common. It is possible, although by no means certain, that it is of uppermost mammuillatum Zone age. Bed 2 has yielded phosphatised or pyritised Hoplites (Isohoplites) eodentatus, H. (I.) sp., Beudanticeras albense, B. sanctaecrucis, Otohoplites sp., Lyelliceras camatteanum (d’Orbigny), Brancoceras sp., indicating the eodentatus Subzone, and its top is an erosion surface. The sediments of Bed 3 contain crushed fossils including ammonites, some quite large, such as Hoplites (H.) spp., Lyelliceras of lyelli Subzone appearance, and Douvilleiceras sp., and can be classified with the basal part of the /yelli Subzone. Bed Lithology Ins M pi Fawn-grey slightly silty clay, shelly, with iron-stained = 6 partings. Some fossils are partly phosphatised. = 1 (11) Black phosphatic nodules scattered in fawn grey silty clay. ~ 344 ” 2 (i) Fawn-grey shelly clay, silty with iron stained partings. 3 = Part-phosphatised and part-pyritic ammonites occur & ae 4 5 scattered throughout. aS “ ——) 2 [—— / Lew eel | ee | | Silty fawn-grey shelly clay with some pyritic fossils | 5 Gi | “. | = ete o4 Fic. 38. Section in basal Gault exposed in the claypit of the Hugenot Freres, situated a few hundred yards E. of the D 61 road, 1 km NNW. of Maurupt, and 1-4 km S. of Pargny- sur-Saulx, Marne. (c) Les Cétes Noires (Haute Marne) Approximately 15 kms SSE. of the section described above is the natural river cliff of Les Cotes Noires situated on the W. bank of the River Marne 1 km to the W. of Moéslain, near St. Dizier. This magnificent natural section can only be safely worked in reasonably dry weather and is approached by way of the summit of the go MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ft Ins M 9 Yellow grey clay. = 15 850 . a ” 8 More calcareous clay with pyrito phosphatic ammonites. 1 7 4 cl ap Blue black micaceous clay with gypsum crystals and scattered phosphatic nodules. - 31 ie) < = 10 | | in | 6 Grey micaceous clay. | 15 6 5 | | s. | ” 2 ~~ Black micaceous clay. a 9 3 © v» ° “ le} Fic. 39. Section in Middle Albian sediments (largely after P. & J-P. Destombes 1965) at Les Cétes Noires, 1 km W. of Moeslain on W. bank of the river Marne (Haute Marne). IN THE ANGLO-PARIS BASIN gi cliff from the D196 between St. Aubin and Laneuville-au-Pont. The section has recently been described by P. & J.-P. Destombes and is quoted in text-fig. 39. It forms one of the original localities cited by d’Orbigny when defining the stage (1842 ; 404) and is doubly important because it shows a complete sequence from the mam- millatum Zone to the spathi Subzone of the dentatus Zone. The outline classification of the sequence is as follows. The eodentatus Subzone is definitely represented within Bed 5 and may include 6 and the basal part of 7. The remainder of Bed 7 together with 8 contains a lyelli Subzone fauna, Bed 8 lithologic- ally represents the NE. extension of a marker horizon recognisable at the top of the lyeli Subzone in the Gault of the Aube and in the St. Florentin area of the Yonne (text-fig. 43). Bed 9 contains a spathi Subzone fauna. (d) Courcelles prés Clérey (Aube) This clay pit, No. 3 of the Tuileries de St. Parres les Vaudes, is situated to the E. of the river Seine on the eastern side of the D 49 about 2:5 kms SE. of Clérey. It now forms the most important section available in the Middle Albian sediments in the Aube, and is typical of the sequence formerly exposed at such famous localities as Dienville on the River Aube, and Gaty-prés Géraudot in the Forét d’Orient (Larcher, Rat & Malapris 1965 ; 246). It is very close to the old section at Courcelles figured by Leymerie (1846 ; pl. 3, fig. 4). The section is given in text-fig. 40, and its correla- tion with sections to the NE. and SW. in text-fig. 43. It has been described briefly by P. & J.-P. Destombes (1965 ; 262), and is particularly important in that it permits a direct comparison to be made with the sequence in the Horton Clay pit, Small Dole, Sussex (p. 35). Bed I to a metre above the base of Bed 4, are classified with the /yelli Subzone, and the following list of ammonites is certainly not exhaustive and represents material collected strictly im situ. Bed 1 is not very fossiliferous but has yielded Hoplites (H.) bullatus, H. (H.) dentatus group, Beudanticeras albense, Lyelliceras pseudolyelli (Parona & Bonarelli), L. aff. gevreyi. Bed 2 (i) Beudanticeras santaecrucis, Brancoceras sp., and on a bedding plane 1 foot (0-3 m.) from the base, Desmoceras latidorsatum is not uncommon and this horizon has also yielded a single example of Hypophylloceras. Bed 2 (ii) Brancoceras sp., Pseudhelicoceras argonnense. Bed 2 (iii) Lyelliceras lyelli, Brancoceras sp., Eubrancoceras aegoceratoides (Steinmann), ‘ Oxytropidoceras’ evanst. Bed 2 (iv) Desmoceras latidorsatum, Beudanticeras laevigatum, B. sanctaecrucis, B. albense, Hoplites (H.) sp. dentatus group, Lyelliceras gevreyi, Brancoceras spp., Protanisoceras (P.) alternotuberculatum, P. (P.) barrense P. (P.) nodoneum. Bed 2 (v) Beudanticeras laevigatum, Hoplites (H.) baylei, H. (H.) sp. dentatus group, P. (P.) alternotuberculatum, Pseudhelicoceras argonnense. Bed 3 Douvilleiceras clementinum, Hoplites (H.) dentatus, H. (H.) baylei, H.(H.) spp. Bed 4 basal x metre is character- ised by Hoplites (H.) spp. but P. & J.-P. Destombes record Dowvilleiceras up to this height, and it is here included in the lyelli Subzone. In comparison with the Horton Clay pit, Small Dole, the fauna listed above shows the following important features. Bed zr must be close to the underlying eodentatus Subzone for Lyelliceras pseudolyelli is directly transitional from Lyelliceras camatteanum MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ft Ins M. in 16 = ry 6 Weathered grey silty clay somewhat marly near the base. = 6 ° & 5 15 = Vv oOo On tate se}— 2 5 Blackish phosphatic nodules in weathered grey silty clay. K 144 13 12 11 10 4 Dark grey slightly silty clay with crushed shells and part pyritised = 34 Te) fossils. Brownish phosphatic nodules are scattered throughout. At 8 = feet trom the base there is a seam of ‘solid’ pyritic ammonites, a Approximately 2inches above the base thereis a similar bedding ? 2) plane with well preserved fossils. 8 | 7. | = =| = = 6 | V 2 | — 4 3 Marly silty light grey clay with large concretions of silty shelly marlistone. 3 (oe ee | (v) Darkish fawn-grey silty clay, shelly with scattered ‘solid’ pyritic 4 fossils 3 (iv) Mottled fawn-grey clay, silty with more numerous ‘solid’ pyritic ammonites. 4 2 (ill) Darkish fawn-grey shelly silty clay with scattered pyritic fossils. A = distinct line of brown cavernous phosphatic nodules occurs 4 inches above x 8 the base, below which the clays become much siltier. ~ E x (ii) Mottled fawn-grey shelly clay silty with ‘solid’ fossils, 8 — (1) Darkish silty fawn-grey shelly clay with a bedding plane of scattered 1 pyritic fossils at the middle, © 1 Oark grey silty clay with scattered line of phosphatic nodules 9inches from (e} the top. ° Fic. 40. Gault section at the No. 3 claypit of the Tuileries de St. Parres les Vaudes at Courcelles prés Clérey on E. side of the river Seine, and to the E. of the D 49 road 2°5 km SE. of Clérey, Aube, IN THE ANGLO-PARIS BASIN 93 of the eodentatus Subzone to Lyelliceras lyelli of the typical development of the lyelli Subzone. Beds 2 and 3 contain a closely comparable fauna to that of the English lyella Subzone except that in England the Tethyan element represented by Desmoceras and Hypophylloceras is absent. Douvilleiceras clementinum is common in Bed 3 at Courcelles but this genus is very uncommon in the lyelli Subzone in England. The species of Brancoceras are somewhat different to those found in England and they frequently show a tendency to a zig-zag arrangement of the ribs as they sweep across the venter. The occurrence of Eubrancoceras aegoceratoides in Bed 2 (iii) is very important for long-range correlation (p. 135). The beautifully preserved fauna of Bed 3 includes also bivalves, gastropods, and corals, and it is this horizon that has yielded many of the fine specimens of Hoplites (H.) spp., and Dowvilleiceras clementinum from such localities as Dienville, Gaty, or just Aube, found in museum collections. The remainder of Bed 4 contains a typical spatht Subzone fauna consisting essenti- ally of species of Hoplites (H.) together with Metahamites sablieri and Inoceramus concentricus. Ata height of 8 feet (2-438 m.) from the base of Bed 4 there is a small thickness of clay with scattered pyritised ammonites and this has yielded to the author a single example of Mojsisovicsia delaruet compressa (Spath). Bed 5 probably represents much of the higher part of the spathi Subzone sediments seen at Revigny-sur-Ornain (text-fig. 37), for the species of Hoplites at the top of Bed 4 are not particularly high forms. Bed 6 above contains Anahoplites sp. indicating the extreme base of the iutermedius Subzone. Larcher, Rat & Malapris (1965 ; 246) considered that the section at Villemoyenne (No. 1 of the Tuileries of St. Parres-lés-Vaudes) showed a mammillatum Zone sequence. However, P. & J.-P. Destombes (1965 ; 263) and Marie (1965 ; table 1) indicated that there was overlap between the sequence exposed at Villemoyenne and that of Courcelles. The pit is extensive and the dip appears to be negligible. It is situated less than 2 kms SE. of the section at Courcelles and 0-5 km along the road from Villemoyenne to Le Ht. Villeneuve. An examination of the sequence has convinced the writer that it is wholly of high mammullatum Zone age, a conclusion which Dr. P. Destombes has also arrived at (personal communication). (ec) La Vendue Mignot (Aube) The Tuilerie Le Clerc, situated about 200 yds W. of the D1 and a few hundred yards S. of the D108 roads at La Vendue Mignot, has been nominated as the type section of the Subzone of Lyelliceras lyelli & Hoplites benettianus by P. & J.-P. Destombes (1965 ; 262, 266). The section is very shallow, like many of the smaller terriers in this region of France, but with the combination of a northerly 3° dip and the slope of the ground surface, approximately 16 feet of weathered clays are exposed (text-fig. 41). The section is situated about 9 kms WSW. of that of Courcelles prés Clérey, and the sequence although well weathered in its upper part is apparently the same. Bed I was seen to a depth of 7 feet (2-133 m.) but yielded no ammonites to the writer. At 2 inches (0-050 m.) above the base of 2 (i) a single example of Desmoceras latidor- 94 MIDDLE ALBIAN STRATIGRAPHY satum (Michelin) was found im situ enabling a direct correlation to be made with Courcelles. Bed 2 (ii) at La Vendue Mignot corresponds to 2 (ii) at Courcelles, but yields a somewhat higher percentage of part-phosphatised fossils. The remainder of Bed 2 is too deeply weathered to permit the recognition of the remaining subdivisions seen at Courcelles, although its fauna grosso modo is the same as that listed above. In the soil at about the middle of the northern face of the pit, there are pieces of well weathered sandy marlstone yielding the fauna of Bed 3 at Courcelles. Although this is the nominated type section of the /yellc Subzone proposed by P. & J.-P. Destombes it shows neither the relationship with the eodentatus Subzone below or the spatht Subzone above. Neither does it show a complete sequence in the lyelli Subzone itself. Bed Lithology efi: Ins M. Fragments of gritty maristone in subsoil. Very weathed buffish silty clay with some limonitic fossils 4 in the lower part. 6 4 = 3 (ii) Slightly lighter clay with part-phosphatised part-limonitic fossils. 8 ~ (i) Weathered buffish silty clay with a few limonitic fossils. 2 fe) 2 Weathered gritty glauconitic buffish clay. 7 le) (0) Fic. 41. Section in Gault at the Tuilerie Le Clerc, c. 200 yds W. of the D 1 road and a few hundred yards S. of the D 108 road, at La Vendue Mignot, on the N. side of the Foret d’Aumont, Aube. (f) St. Florentin area (Yonne) The early work of Ebray (1863) and Hébert (1863) did not present a true picture of the Albian succession in the area of St. Florentin, and Lambert (1894, I913) was the first worker to give a more correct sequence. Lambert’s sequence was the one IN THE ANGLO-PARIS BASIN 95 quoted subsequently by Lemoine (1910). Houdard (1933) confirmed Lambert’s observations and presented accurate and important new information. More recently P. & J.-P. Destombes (1965 ; 264-265) have reinterpreted the sequence indicating a facies change certainly within the spathi Subzone between St. Florentin and Montléhu a distance of barely 1 km. In this area the clay facies of the Perthois (the strip of country flanking the Chalk and including portions of the Départements of the Haute Marne, Aube, and Yonne) gives place to the predominantly sandy facies of the Puisaye (the similar strip of country stretching from the River Armance to the Loire). No sediments of eodentatus Subzone age have been proved in this area. Although known to occur, lyelli Subzone sediments are no longer exposed, but from sections which existed formerly at St. Florentin, and to the SW. near Mont St. Sulpice, Seignalay and Beaumont, it is readily apparent from the old collections that the equivalent of Bed 3 at Courcelles is present. The fauna is the same but it is pre- served in a much grittier and pebbly matrix. Two sections in sediments of spathi Subzone age exist in this area today. Montléhu The Tuilerie Montléhu is situated immediately S. of the N77 at the village of that name. It exposes about 18 feet (5-48 m.) of weathered grey clays with crushed Hoplites (H.) spp., and Inoceramus concentricus, and is classified without doubt with the spatht Subzone. As one proceeds SW. the topography changes quickly, and St. Florentin is built upon the high ground formed by the essentially sandy deposits of both Middle and lower-Upper Albian age. Sabliére Binot This disused sandpit in the Sables de Frecambault at the SE. end of the town of St. Florentin is situated on the same quarried escarpment as that described by Houdard (1933 ; 47). The pit, which is now being filled in, shows sediments of Middle & Upper Albian age (text-fig. 42). It has been mentioned by P. & J.-P. Destombes (1965 ; 264), and Marie (1965 ; table opp. p. 286) who includes additional information on the other sections in the area. Bed 1 has not yielded fossils but it lies above the equivalent of Bed 3 at Courcelles (Lyell Subzone), known to be present in this area. It is almost certainly of spathi Subzone age and is considered to be the equivalent of the clays exposed at Montléhu. Bed 2 shows the incoming of clay sediment and it seems to the writer that this part of the sequence is more likely to have been deposited at the same time as the clays at Montléhu. However, the only fossils found are phosphatised bivalves. Dr. P. Destombes has informed me that large Hoplites (H.) were obtained from Bed 3 during the quarrying operation. Bed 4, the Bed VII Graviers 4 Opis glareosa of Lambert, is of considerable interest. It can be divided into two very irregular subdivisions. A lower dark grey sub- division with Hoplites (H.) spp., derived from the spathi Subzone, and an upper 96 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ft Ins M, a aa a . a - | | 7 Soft maim with buff phosphates and pyritic concretions. | 3 ° 16 Blocky sandy yellowish maim. Z 1 fe) SSS 1% he 15 _< le Wi jo a 5 | 14 = Alternating broad seams of gritty clay and sandy beds Incompletely | 10 6 seen. | | | 13 Ig Is 12 ee ieee ee —_— — —- |: Grey gritty clay seen clear for: re 4 Coarse pebbly sandy loam with admixed ape) clay. Phosphatic nodules occur 5 o LE in roughly two concentrations (see text). = 7 3 Coarse hard phosphatised pebbly Stone=pand: dark-grey in top 4 inches with L phosphatic nodules. jel Ser : we 8-16 4, 2 Coarse pebbly loamy sand with streaks of grey clay. 1 6 104 (v) Coarse yellowish pebbly sand. 6 fo) 9 (iv) Lenticles of sandstone. 1 ° =a (lil) Coarse yellow pebbly sand. 5 8 = 7 = x a n a Lenticles of sandstone. 1 te) 1 6 | | S 4 (i) Coarse yellow pebbly sand. 20 fo} 3 2 1 = = = ° Fic. 42. Section in the Sables de Frecambault at the Carriere Binot, on the escarpment at the SW. end of St. Florentin, a few hundred yards N. of the lane leading to Crécy, Yonne. IN THE ANGLO-PARIS BASIN 97 lighter coloured subdivision which contains some material scoured out from the spathi Subzone sediments, and a predominant element derived from sediments of intermedius Subzone age. Indigenous Anahoplites intermedius and Inoceramus concentricus occur in the upper subdivision indicating that it is undoubtedly of intermedius Subzone age. The derived intermedius Subzone material includes species of Anahoplites which occur at the extreme top of the sfathi Subzone and basal part of the intermedius Subzone in England. Bed 5 is still pebbly in its lower 1 foot (0-30 m.) but it has not yielded fossils to the writer. Marie indicates that at about the middle of Bed 5 at the base of an argil- laceous member the Upper Albian commences. (g) Summary The sections described briefly above provide a picture, albeit very imperfect, of Middle Albian sedimentation across the basin of deposition extending from the Kimmerian modified Palaeozoic massifs of the Ardennes on the NE. side to those of Morvan to the SW. (text-fig. 43). The only information available about the sediments of eodentatus Subzone age come from the sections near Maurupt and Les Cotes Noires, inthe NE. It is acurious fact that as yet it has not been detected in the Aube or Yonne. This must be due to a lack of exposures for the sequence in the mammuillatum Zone in the area of the Bois de Perchois (Aube) is very thick and the Middle Albian sediments here are also apparently of considerable thickness. In England deposits of eodentatus Subzone age are in general very condensed and ammonites are not common except at a very few localities. Species of Hoplites (Isohoplites) form the majority of the ammonite fauna, and its usual associate in France Lyelliceras of the camatteanum group, is exceedingly rare in England. Deposits of lyelli Subzones age already proven at Clermont-en-Argonne are also apparently thicker at Les Cétes Noires than in the Aube, but the lithological sequence is comparable from Les Cétes Noires to the St. Florentin area (Yonne). At Revigny-sur-Ornain it is obvious that the spathi Subzone is represented by thick sediments especially the upper part. Unfortunately, the top of the Subzone has not been exposed at Les Cétes Noires, but at Courcelles the upper part of the Subzone is represented by a single nodule bed. No information is available about the sequence until the St. Florentin area is reached where, between Montléhu and St. Florentin itself, there is a change from the argillaceous facies of the Aube to the sandy facies of the Puisaye. The intermedius Subzone is now known from five localities. It is quite thick at Revigny-sur-Ornain and the top of the Subzone was not determined in the sequence. | Intermedius Subzone ammonites were determined by Breistroffer at Montierender (Haute Marne) and Le Plessis (Aube) (P. & J.-P. Destombes 1965 ; 262). Only the basal part of the Subzone has as yet been determined at Courcelles. At St. Florentin and at other localities in the Puisaye, the Subzone is represented within condensed deposits. No other Middle Albian Subzones are as yet known in this area. Very little information is available about the stratigraphy of the Gault between i@ c i 98 MIDDLE ALBIAN STRATIGRAPHY ST FLORENTIN MONTLEHU LA VENDUE COURCELLES Les COTES MAURUPT M. Ft. MIGNOT NOIRES 30-7109 a ? ? 2 ? ? ? ? ae os nw mt 4 INTERMEDIUS 2' ? ? ? 2 80 ( SK “Po eny i we N 70 . » N \ eaAEHy SPATHI we ‘\ (lower) ty \ Oy Ne e 60 ) ) 15.50 ? 2 ? ? 2 faa oes oo el (fea == SSH a at |e, age) LYELLI 40 7— 10 7 30 S 2 EODENTATUS ™ aw = ? ? 20 a7 7 ? ? 7 5 |——- 10 6 oto subzonal correlation lines {}thological correlation lines REVIGNY sur ORNAIN 1c) Fic. 43. Correlation of Middle Albian sections from the Meuse to the Yonne. 4 IN THE ANGLO-PARIS BASIN 99 this area and the Pays de Bray. However, a comparison between the succession shown by the La Chapelle boring at St. Denis, Paris (Jukes-Browne 1900 ; 397) and that of St. Florentin (Yonne) and Villers St. Barthélemy in the Pays de Bray below shows that the predominantly sandy beds in the Yonne, fringing the massif of Morvan, give way to clays under Paris, but the sequence is thinner. The sequence thickens again northwards from Paris, and in the Pays de Bray the Middle Albian is represented by clays, and the Upper Albian by an Upper Greensand facies. The clay facies extends down to include at least the top of the mammillatum Zone towards the NW. end of the Bray. (iii) PAYS DE BRAY The Pays de Bray both geologically and scenically resembles the Weald (text-fig. 33). The NE. side of the Bray dips very steeply beneath the Chalk and there is no information on the sequence on this side. However, at the NW. end and along the whole of the south western side the dip is much more gentle and brick-pits in the Gault have been opened at a number of places. Usable information has been ob- tained from only four of these : Briqueterie Ledoict, St. Martin, at the NW. end of the Bray (P. Destombes 1970 and im Pomerol & Feugueur 1968) ; a section near Forges- les-Eaux (P. Destombes 1958) ; and two sections in the area of Villers St. Barthélemy (J.-P. & P. Destombes 1938b). The position of these sections is indicated on text-fig. 33. The most detailed information on the Middle Albian sequence in this region yet published is contained in the two papers already cited by J.-P. & P. Destombes (1938b) and P. Destombes (1958). They demonstrate the presence of the eodentatus, lyel, spathi and intermedius Subzones all in a clay facies. The niobe Subzone is indicated as being represented by sandy deposits (P. Destombes 1958) but no definite evidence has been published to support this. This is followed by a break in the sequence involving the remainder of the Middle Albian. (a) Villers St. Barthélemy Two sections were described by J.-P., & P. Destombes in this area (1938b ; 122, 123). Their section 1 is no longer exposed but showed deposits of both the spathi and intermedius Subzones which together are over 30 feet thick (9:15 m.). Section 2 is now well exposed and shows the sequence given in text-fig. 44. Bed 1 (ii) contains Otohoplites spp. including O. destombesi, Beudanticeras spp. and _ Douvilleiceras spp., indicating the uppermost part of the mammullatum Zone. No _ fossils were seen in the lower part of 1 (iii) and it is not possible to say whether it is of eodentatus or basal lyelli age: the top of I (iii), however, contains crushed Hoplites (H.) spp. Bed 2 contains a good bivalve fauna but only a few crushed specimens of Beudanticeras cf. laevigatum, Protanisoceras (P.) sp. cf. barrense, and in Dr. P. Destombes’ collection, a few examples of Lyelliceras lyelli. This bed definitely can be classified with the lyelli Subzone, as also can Bed 3 on the occurrence of a few crushed Beudanticeras at about the middle of the sequence. The basal part of Bed 4 | 100 MIDDLE ALBIAN STRATIGRAPHY however, contains large crushed Hoplites (H.) including H. (H.) cf. dentatus and H. (H. cf. maritimus sp. nov. indicating the lower part of the spatht Subzone. How much of this sequence overlaps that of section I, if at all, cannot be determined. Un- fortunately, during 1967 this section was rapidly expanded, and the higher part of the sequence seen in a rise has now been quarried away. Bed Lithology Ft Ins M Weathered grey silty clay with large partly phosphatised ammonites. Shells are replaced by pyrite. 4 Dark grey somewhat silty glauconitic clay with occasional . 8 0 3 phosphatic nodules. 2 Fawnish grey clay burrowed by dark grey clay witha few 4 ° crushed fossils with pyrite replaced shells oN | I | | I | W spathi lyelli (il) Sandy glauconitic green grey clay with sandy pockets particularly in the lower part. t PREOe = Z 0 Fic. 44. Section in Gault in a claypit 0'8 km N. of the village of Villers St. Barthélemy, c. 150 yds E. of the D2 road, Pays de Bray. (b) Forges-Les-Eaux, & St. Martin Further north in the Pays de Bray, the eodentatus and lyell1 Subzones sediments expand considerably and consist of shelly clays. The section in the Briqueterie Ledoict near St. Martin l’Hortien situated at the NW. end of the Pays de Bray has been described by P. Destombes, who introduced the writer to it. It shows a good development of clays of eodentatus Subzone age overlying high mammullatum zone clays (see P. Destombes 1970 & in Pomerol & Feugueur 1968 ; 129-130, where the locality is given as Bully). The lyelli Subzone is known from a section west of Forges-Les-Eaux where Fortin collected phosphatic and pyritic Lyelliceras with the shell, now in the Muséum d’Histoire Naturelle, Rouen, which were recorded by P. Destombes (1958 ; 309). IN THE ANGLO-PARIS BASIN 101 However, no detailed information on the sedimentary sequence in this Subzone in the northern area of the Bray has as yet been recorded. (iv) COMPARISON BETWEEN THE PAYS DE CAUX AND THE ISLE OF WIGHT The expansion of the sequence towards the NW. end of the Pays de Bray apparently increases further to the NW., for the deep boring at Puys, near Dieppe, showed a very considerable thickness of clay (Jukes-Browne 1900 ; 398). However, an unknown thickness of this clay must be of Upper Albian age, representing a facies change from the Upper Greensand sequence seen in the Pays de Bray. Jukes-Browne is probably wrong (1900 ; 398) in classifying only the lowest 6-7 feet (2 m.) of sandy black clay of the core with the Lower Gault, but in the absence of palaeontological evidence, the boring cannot be interpreted. In the Pays de Caux a somewhat different facies is seen reflecting the proximity of a marginal area of Middle Albian deposition. The Albian sediments of the Pays de Caux (Seine Maritime) are well exposed in the cliffs between St. Jouin and Le Havre. The Upper Albian Gaize rises from sea-level at the base of the Chalk cliffs to the N. of St. Jouin followed quickly by the Gault, and the top of the underlying Poudingue ferrugineux. Below these pebbly beds are sands of Upper Aptian age. In the area between Octeville and St. Adresse these sands are seen to rest upon Kimeridgian sediments, and in this area the whole sequence of Lower Cretaceous sediments can be seen sandwiched between the Chalk and the Kimmeridge Clay. However, along the entire coast from St. Jouin to Cap de la Héve a large number of rock falls tend to obscure the lower part of the Albian sequence in particular, nonetheless, it is possible to make out the succession at many points. Lennier (1867) first described the succession and provided the foundation upon which subsequent stratigraphic work has been based. His is still the only published section of the sequence at Cauville (1867 ; plate 4). The early history of research was summarised by Jukes-Browne & Hill (1896) who made the first major attempt to correlate Upper Albian and Cenomanian sediments in the Pays de Caux with those of southern England. Hill also provided some information on earlier Albian sediments and gave the first detailed accounts of the Albian sequence seen between Octeville and Ste. Adresse. Jukes-Browne (1900 ; 395-401) reviewed the Albian sediments in this area, presenting a useful picture but without any real detail. Subsequent stratigraphic work has tended to concentrate on the sequence at Cap de la Héve, as for example the recent important studies by P. Destombes (1958), Cayeux (1960), and Rioult (1962). Destombes (1958 ; 306-308) sets out to describe the Albian sediments between Le Havre and St. Jouin but, and this is important, he bases his account of the stratigraphy on the sequence seen at Cap de la Héve and Octeville. His classification of these sediments gives a good picture of the zonal sequence in this area. Cayeux (1960 ; 21-25) quotes large extracts from Destombes’ paper, but adds to this important new information pointing out that the sequence in the Poudingue at Cauville shows marked lithological variation to those seen elsewhere. The account by Rioult (1962 ; 39-42) of the section at Cap de la Héve is very useful and he 102 MIDDLE ALBIAN STRATIGRAPHY also presents a comparison with the Albian sequence in the Isle of Wight and the Dorset and Devon coastal area. All three papers ably summarise the earlier literature. As Cayeux (1962 ; 2) has pointed out, the stratigraphy of the Albian sediments between Cap de la Héve and St. Jouin needs revision. Such a revision requires patient study because of the rarity of age diagnostic fossils. The following account is quite obviously incomplete but it adds some new information on the succession and provides a much more accurate foundation for the correlation of the sediments seen in the Pays de Caux with those of the Isle of Wight. In this section of the work the full exposed sequence of the Aptian and Albian sediments up to the base of the Gaize is recorded. The terms ‘ Poudingue ferrugineux ’, & ‘ Argiles du Gault ’ of Lennier (1867) cannot be accurately delimited in all the sections. It is essential that these sections are worked with the greatest care particularly in the early spring months. Winter frosts and the general freezing of ground water cause the shattering of the Chalk in the cliffs and large blocks can be dislodged merely by the ringing note of a hammer or by the slight vibration of a heavy surf. Major cliff falls are not infrequent during the early months of the year, but the collecting is far better at these times ! The sections described below indicate that the cliffs between St. Jouin and Cap de la Héve present a cross section through a depositional trough. The Lower Albian sediments are slightly comparable to those of the Isle of Wight, but those of the Middle Albian are quite different. (a) St. Jouin The section described in text-fig. 45 is exposed about 300 yds S. of the cliff-top car park west of St. Jouin. It has not previously been described, and includes Lower, Middle and Upper Albian sediments up to the base of the Gaize. Unfortunately no age diagnostic Middle Albian fossils have been found here by the writer and the correlation of this section with that of Cauville (text-fig. 49) is based purely on the lithology, and is, therefore, suspect in detail. (b) Cauville From approximately 50 yds SW. of the waterfall to about 300 yds NE. of it there are good sections interrupted by cliff falls (text-fig. 46). As Cayeux has indicated (r960 ; 23), there are striking variations in the Poudingue, the sediments of the mammullatum and ?tardefurcata Zones, in this area. This is well shown in the four sections described here for the first time, however, the Middle and Upper Albian sediments remain reasonably constant. Beds 1-9 are of Lower Albian, essentially mammillatum Zone, age. In the Bucaille collection in the Muséum d’Histoire Naturelle, Rouen, there are three specimens of Hoplites (Isohoplites) and one specimen of Hoplites (H.) which come from Cauville. They are preserved in blackish phosphate with traces of the inner nacreous layer of the shell preserved, and with evidence of pyritic inner whorls and glauconitic loamy ite] a a 14 Ww — N FIG. 45. IN THE ANGLO-PARIS BASIN Lithology First concretionary stone band of the Gaize. Tough blocky grey sandy malm with scattered pale phosph- atic nodules. Argillaceous dark grey silty glauconitic sediment resting on the guttered upper surface of Bed 13 below, becoming more of a clay upwards, then passing into about 6 inches of hard shaley grey shelly clay. Highly glauconitic blackish loam resting ona guttered surface of Bed 12 below, Pyritic concretions occur throughout. Highly glauconitic very dark grey loam a bit pebby passing down by rafts into sparsely shelly loam resting on guttered surface of Bed 11 below. ough tawn sandy clay with brown phosphatic nodules with dark interiors, septarian at the top. Very pebbly grey loam with crushed bivalves, Dark grey less pebbly clay than Bed 8 with intercalations of dirty yellowish sand. Scattered nacreous shells. occur, Pebbly dark grey ill-graded fossiliferous sandy clay with nacreous shells preserved. Hard gritty concretions in tough grey pebbly clayey matrix. Tough ill graded ferruginous loam with phosphates & grit. Ferruginous pebbly sand with some streaks of grey clay. Lenticles of grit occur near the top. Scattered sandy phosphatic nodules in brown pebbly sandy loam. Rather pebbly streaked grey loamy clay and brown sand, Mottled grey sandy clay-loam, and brown sand less pebbly than Bed 1 into which it passes, Pebbly dark grey green loam with streaks of brown sand becoming fewer downwards. In the top of the bed there occur pebbly concretionary sandstone lenticles 4-Sinches thick. 103 fe} Sequence in the Poudingue and Gault in the sea-cliff, c. 150 yds SW. of the cliff path exit, St. Jouin Bruneval, Pays de Caux. Lithology Bed | 16 | Hard light-grey concretionary sandstone, Basal bed of the Gaize. | 15 | Light-grey cross-bedded sandy marly clay with a few concretions. Grey glauconitic claytoam with black, buff-rinded, phosphatic nodules at top and. bottom (v) Dark grey glauconitic slightly pebbly loam. 13 (iv) Thin seam of irregular blackish light-rinded phosphatic nodules in loam. / (iii) Lighter grey glauconitic sparsely shelly loam, (ii) Thin seam of scattered blackish light-rinded phosphatic nodules in loam. (i) Darkish grey glauconitic shelly loam, | | | i | | | | | | | | | | pares | Streaked dark green glauconitic sandy pebbly loam, with a few phosphatic nodules, } Very shelly gritty glauconitic fawny pebbly loamy clay with rolled fragments of fawn clay in the basal few a 12 inches, pebbly patches at the top, and a few concretions. S a Black clay channelled into the b low. Wwe > 9 Irregular bed of pebbly ferruginous sand with large quartzite pebbles and phosphatic nodules, fp Grey greenish glauconitic loam with a 4inch thick oxydised zone at the top, In the two end sections there is a single bed of grey pebbly sandy concretions, very hard, with phosphatic nodules in the lower part, | 8 Between the two end sections, an upper bed of less pebbly grey green sandstone lenticles appearsin the sequence. The lower lenticles are underlain by dark grey pebbly glauconitic loam with gritty and pebbly phosphatic nodules at the base. 190 yds NE of waterfall Between path and waterfall (vi) Tough mottled brown-dark grey loam becoming coarser and darker upwards with pebbles at top. (v) Grey green pebbly glauconitic loam with patches of pure quartz sand, the whole extensively burrowed (v) Dark grey sandy clay and yellowish sand with line of irregular ey phosphatic nodules at top and Gv)iEuwinish) pebblyniicam small Hard placquettes at the base. (iv) Variegated greenish grey-brownish loam, (iii) Very pebbly grey-green loam, (iii) Coarse glauconitic loam. (ii) Bed of pebbles with a few gritty phosphatic (ii) Thin ferruginous pale-hearted fine-grained nodules. concretions, a few pyrite nodules and wisps of white sand, (i) Coarse glauconitic loam, together with brown phosphatic nodules. KITCHINI (ii) Mixture of ferruginous sand and blackish clay in streaks. | | | | | | | | | (i) Dark grey gritty glauconitic micaceous clay with | | | (i) Coarse dirty yellow sand. | | | Grey sandy clay and dirty yellow sand mixed together in a mottled loam, Yellowish bedded sand with glauconite: some thin—bedded and cross-bedded units. Nodules of phosphatised grit occur scattered throughout, Irregular shaped masses of ferruginous pebbly grit. Dirty yellow sand with glauconite, (v) Concretions of massive ferruginous pebbly grit, with interstitial yellow sand. (iv) Yellowish sand. (iii) Slightly cemented ferruginous pebbly grit passing into 5 (iv) above. (ii) Coarse yellowish sand grading into 5 (iii). (i) Ferruginous pebbly cemented grit grading up into 5 (ii). 300 yds NEof the 270 yds NE of the 190 yds NE of the Between path and waterfall waterfall waterfall waterfall o "1 ° oJ 3 6 3 o 74 -. 6 r* ae : 0 64 Peg ate ; “lat a 54 Bie “a fe) 6 7 all ° ) ° 10 2 2 9 1 6 Fic. 46. Section in Poudingue and Gault in the sea-cliff at Cauville, : Pays de Caux (Seine Maritime). 106 MIDDLE ALBIAN STRATIGRAPHY Bed Lithology Ft Ins M First concretionary stone band of the Gaize. pit) cI=F] 12 Silty glauconitic mid-grey clay at base becoming siltier and 6 ce) lighter in colour upwards as clay content decreases. 11 Phosphatic and pyritic nodules occur scattered throughout. Definite break in sequence at the base. 10 Tough mid-grey, sparsely shelly slightly glauconitic clay, silty at base, becoming progressively less silty upwards. Scattered shells occur throughout. ao °o W oS Dark grey-greenish glauconitic loam with scattered shells. Thin seams of light-rinded brown phosphatic nodules occur as shown. The basal line contains gritty phosphatic nodules, the uppermost line contains septarian phosphatic nodules. I> TU Dark grey—black greenish tinged glauconitic loam; a little 7 pebbly with very scattered gritty phosphatic nodules, and shells, Definite break in sequence at the base, 6 Dark grey—green glauconitic loam with small phosphatic nodules, and shelfs. Transitional bed with upwards. Dark brown = = dark gre sand lay content increasi hosphdtic. tg d bottom. 9 10 5 ic nodules top an Brownish sand with a 1-2inch bed of pure running grit at the A ro) = oa 3 5 4 base. The sand is slightly glauconitic in the lower half, but upper half is seamed with glauconitic wisps. 4 = 3 Hard dark brown very pebbly indurated grit with a few 2 ie) LL phosphatic nodules. 3 Mottled brown and dirty yellowish sand with a few brownish 2 clay wisps, becoming ferruginous in the upper foot or so. 4 2 = 2 Heavily bioturbated mottled loam consisting of a churned-up 1 mass of grey sandy clay brown and dirty white sand in 6 4 wisps and pockets. Bed becomes more sandy downwards, 1 and contains scattered soft buff phosphatic nodules, ie) Fic. 47. Section in Poudingue and Gault in the sea-cliff immediately to the NE. and below the cliff-top car-park, Octeville, Pays de Caux. IN THE ANGLO-PARIS BASIN 107 matrix. This matrix is very similar to Bed 11. Bed 12 at the base shows angular pieces of clay indicating heavy erosion of previously deposited clay sediment. The bed itself is sandy and contains very fragile but well preserved Inoceramus concen- tricus, Anahoplites planus, A. splendens, and Dimorphoplites miobe, indicating the niobe Subzone not previously recognised in the Pays de Caux. The loams of Bed 13 also contain J. concentricus in the lower 1 foot 3 inches (0-38 m.) but apparently no ammonites. Post eodentatus Subzone Middle Albian sediments are, therefore, present in this area. The Upper Albian sediments probably commence at some level within Bed 13. (c) Octeville This section (text-fig. 47) also has not yielded age diagnostic Middle Albian fossils to the writer. It is situated in the cliff immediately to the NE. of the cliff-top car park, and again has not previously been described in detail. The lithological correla- tion with the sequence at Cap de la Héve and Cauville is, however, more definite than that of St. Jouin and Cauville (text-fig. 49). (d) Cap de la Héve This famous section can be seen high in the cliff on the northern side of the Cap (text-fig. 48). It has been studied by a number of workers, but the best recent description of the sequence is that given by Rioult (1962 ; 39-42). Cayeux (1960 ; 25) has recorded Goodhallites goodhalli from the base of the bed here numbered 6, and Bed 4 is of mammullatum Zone age. In the Bucaille collection at Rouen, there is a single example of Hoplites (H.) preserved in blackish, gritty phosphate stated to have come from Cap dela Héve. The preservation is identical to fossils found occasionally in Bed 5 which, therefore, probably contains eodentatus and possibly basal lyelli Sub- zone fossils in remanié. (e) Summary, and comparison with the Isle of Wight The lithological correlation of the sections described above is shown in text-fig. 49. It can be seen that Lower and Middle Albian sediments reach their maximum develop- ment in the area of Cauville. Eodentatus Subzone sediments are present at all localities with the possible exception of St. Jouin where it has not been proved. At Cauville, the eodentatus Subzone is apparently less condensed, and is followed by sediments of the mio0be Subzone. To what extent higher Middle Albian sediments are present, if at all, is unknown at this time. At Cap dela Héve it appears that Upper Albian sediments rest directly upon the residue of basal dentatus Zone age. Even if the classification of these sections is unsatisfactory, it is immediately apparent that all previous correlations of the ‘ Argiles du Gault ’ of the Pays de Caux with the Gault of the Isle of Wight are no longer tenable(p.42). It appears that the sequences in the Isle of Wight and the Pays de Caux are truly out of phase. In the Isle of Wight the kitchint Subzone of the mammillatum Zone (Lower Albian) is 108 MIDDLE ALBIAN STRATIGRAPHY represented vemamnzé in the basal pebble bed of the Carstone ; in the Pays de Caux it is well developed at Cauville. The eodentatus Subzone is represented at the top of the Carstone by sediments containing indigenous Hoplites (Isohoplites) ; in the Pays de Caux it is present but very condensed even at Cauville. The major difference, how- ever, occurs in the Gault. In the Isle of Wight the clays are of lyellt, spatht, and probably intermedius Subzones age, followed possibly directly by some orbignyi Subzone sediments (Upper Albian) ; the bulk of the loricatus and the whole of the lautus Zone being absent. In the Pays de Caux no sediments of any of the Subzones mentioned above have yet been detected. However, the niobe Subzone is present at Cauville, although absent in the Isle of Wight, and the lowest Upper Albian Subzone yet proved is varicosum. Bed Lithology 8 Basal Ienticular marly sandstone concretions of the Gaize, 7 Light grey micaceous silty malm. 6 Mid grey silty micaceous clay becoming a highly glauconitic Ins M varicosum loam by the middle of the bed. 5 Very pebbly ill-graded greenish loam with pebbly phosphatic nodules. \[eod. re peers Massive indurated blocks of pebbly pale-brown grit in a matrix of loose similar material. Darker brown ill-graded pebbly grit with streaks of dark grey clay. Lenticles of indurated material occur, Loose pebbly brown grit with little clay, A few scattered phosphates) Very coarse brown ill-graded pebbly grit, loamy with streaks of grey brown clay in the middle. Large blocks of brown hard sandstone, as shown, inlower mottled yellow sand & fawn loam. mammillatum Fic. 48. Section in Poudingue and Gault in the sea-cliff on the N. side of Cap de la Heéve, 100 yds N. of the lighthouse, Ste Adresse, Le Havre, Pays de Caux. It is probable that the Isle of Wight and the Pays de Caux belong to two separate depositional troughs (p. 142) and do not form one area of deposition as implied by previous workers. The sediment of the ‘ Argiles du Gault’ is a sandy loam rather than a clay and small pebbles are present. This together with the Poudingue below indicates the close proximity of a shoreline but outcrop and borehole information indicate that this could hardly be to the south (see p. 142). 10g IN THE ANGLO-PARIS BASIN 3A3H V1 30 dv5 SNNNAZ190 YyOd-}/DjsdDM SN SPAOEL aTNANYS SN spAOL2 ‘QUIIJIIeJ, UTES ‘xNeQ 9p SAvg oY} JO SHIO-eas 94} UI SUOTI}DeS JO WOT}RIEIIOD $2uUl} UO}ZO|2I40> jo21!Gojoyzi7 — -——- — —. 3N SPAOOE Ninor is wo OL Oz. Sz O€ ol SE. Ov- Gv. SL os ss 110 MIDDLE ALBIAN STRATIGRAPHY With the completion of the description of the individual sections in England to- gether with a brief review of those in France, it is now possible to consider in detail the Zonal and Subzonal scheme of the Middle Albian. It is instructive and sobering to examine also the history of the development of this particular scheme, not atypical of many zonal schemes. There are workers who would insist that zonal schemes should be fixed for all time with little regard to future detailed work, or whether the scheme is based upon firm foundations. IV. DEFINITION OF THE MIDDLE ALBIAN SUBSTAGE AND ITS ZONAL SCHEME IN THE ANGLO-PARIS BASIN A. Historical background The Formation name Gault was accepted in much the same sense by English and French geologists within the first half of the 19th Century. The history of its use in England was given by Jukes-Browne (1900 ; 14-31). D’Orbigny took William Smith’s concept, that individual formations could be determined by their fossil con- tent, a major step forward when he recognised that fossils characteristic of one litho- logical unit occurred in different lithologies and that these, although deposited at different localities, were formed at the same time. He erected, therefore, a series of chronostratigraphic stages to include these diverse lithologies. Apart from the localities mentioned by d’Orbigny (1842 ; 404-5) in his definition of the Albien stage (latinized to Albian), he recorded others in 1849 (¢m Geinitz 1849 ; 6-7). Pictet & Campiche adopted d’Orbigny’s stage name when they commenced their description of the Cretaceous fauna of Ste Croix, Vaud, Switzerland, subdividing it into Albien infériur, moyen and supérieur (1858 ; table facing p. 27). De Rance (1868 ; 163-171) was the first worker to describe the Gault section at Folkestone in detail. He accepted d’Orbigny’s term Albian and divided it into lower and upper divisions drawing the boundary between them at what is now known as the junction between Beds VIII and IX. The lower division corresponds approx- imately, therefore, to Pictet & Campiche’s Albien moyen. He recognised eleven beds in the Folkestone Gault and referred each to a zone based on its characteristic fossil ; employing essentially the characteristic ammonite. Later Price (1874 ; 342-368) revised De Rance’s description but neither of these workers on these occasions attempted to apply their zonal scheme to sections other than at Folkestone. Barrois (1875b ; 707~714) was the first geologist to formally define a zonal scheme for the Albian of the Anglo-Paris Basin in the sense that we use today. This idea of the application of an index fossil denoting a segment of time and represented by different types of sediment, or none at all, differed from that of De Rance & Price who used them merely in a local sense for an actual lithological unit. However, the idea crystallised by Barrois for the Albian is implicit in the writings of earlier French workers including d’Orbigny. Barrois recognised a tripartite division into :— Zone a Ammonites inflatus Zone a Ammonites interruptus Zone a Ammonites mammillare Of these only the lower two zones were included in the Albian, the Zone 4 Ammon- IN THE ANGLO-PARIS BASIN IIt ites inflatus being included by him in the Cenomanian. Nonetheless, the terms ‘ Zone of Ammonites mammilare ’ and ‘ Zone of Ammonites interruptus ’ were first used by De Rance (1868) at Folkestone. Barrois stated that the type area of the interruptus Zone was the Aube but he recognised that in this area there was a mixture of what he thought to be the fauna of the mammillare Zone (e.g. Dowvilleiceras of the clemen- tinum group) and that of the interruptus Zone in the clays classified with the latter Zone. In 1878 (265, footnote) it was obvious that Barrois was worried by this admixture for he states that possibly Ammonites lyelli might have been preferable as the index of this zone ; this species being characteristic of the clays of the Gault classified with the interruptus Zone from the Aisne to the Yonne. Price & Delatour (1879 ; 38-42) concluded that all the beds of the Lower Gault at Folkestone had their representatives in the Gault of the Aube, but neither of these workers had seen the sections on the opposite side of the Channel. Price and Barrois knew each other, and it is significant that Price also refers to a Zone of Ammonites lyelli and places it above the Zone of Ammonites mammillaris. Barrois, like many of his contemporaries in France, when considering the zonal scheme, was strongly influenced by the very full development of the mammillatum Zone, and the eodentatus and /yell1 Subzones in the Gault of the southern part of the Paris Basin. Although Barrois knew the sections at Wissant and Folkestone, and realised that there was a break in the succession below the sediments of the inflatus Zone, he does not appear to have fully grasped the extent of this gap in the observed sequence in the Aube and, therefore, the reason why the sequence in the Aube appeared so different from those on each side of the Channel. The observed gap in the southeastern area of the Paris Basin involves the equivalent of the greater part of the Lower Gault at Wissant and Folkestone, and includes all from the top of the intermedius Subzone to the base of the cristatum Subzone. Whether there is a total absence of deposits of this age in this area is uncertain (p. 97). Jukes-Browne (1900 ; 45) adopted the Zone of Ammonites interruptus but restricted it to beds of equivalent age to that of Bed I at Folkestone, the interruptus Zone of De Rance in part and Price. This reading, excluding the equivalent of the “Sulphur Band’ brought the English interpretation more into line with the known sequence in the Aube. He realised that the remainder of the Lower Gault at Folke- stone could not be classified with the interruptus Zone, and he proposed that Beds II to VII and their lateral equivalents be included in a Zone of Ammonites lautus. He excluded Bed VIII from both the lautus and rostratus zones (the latter being the equivalent of Barrois ’ Zone a Ammonites inflatus) treating it as a junction bed. Because Barrois had classified his Zone 4 Ammonites inflatus with the Cenomanian, Jukes-Browne felt that he could not accept d’Orbigny’s name Albien for the stage. He had proposed the name Devisian to encompass the Gault and Upper Greensand of England (1892 ; 266), but this name clashed with the earlier Oxfordian substage name Divesian and the term was replaced by Selbornian (1900 ; 30-31). In reality there was no need for a new name and the terms Devisian and Selbornian are synonyms of d’Orbigny’s Albian. Jukes-Browne’s zonal scheme and stage name (1900) were employed in England until Spath commenced work on the nomenclature of the Albian (1921). Er2 MIDDLE ALBIAN STRATIGRAPHY Kilian (1907 ; 62, 67) presented the following scheme influenced probably by the work of his pupil Jacob. 4 Zone der Schloenbachia (Mortoniceras) inflata Sow. sp. (mit zwei Subzonen) 3 Zone des Hoplites dentatus Sow. sp. und Acanthoceras Gault stufe lyelli Leym. sp. (Albien D’ORB.) 2 Zone des Hoblites tardefurcatus Leym. sp. und Hoplites vegularis Brongn. sp. I Zone des Parahoplites Nolani Seunes sp. (sog. Milletianusschichten) und Douvilleiceras nodosoco- statum D’ORB. sp., D. Bigoureti Seunes sp. For the first time Lyelliceras lyelli is used formally in a zonal scheme. Jacob’s thesis was completed in 1907 but not published until the following year (1908 ; 208— 590, pls. I-VI) when he presented the stratigraphical results of his study of the middle part of the Cretaceous of the French Alps and adjoining regions. He divided the Albian into the four zones which appear in Kilian’s work but in a simplified form. His scheme is as follows (1908 ; 296). VIb_ Sous-Zone a Mortoniceras inflatum Sow. sp. et Turrilites bergert Brong. VIa Sous-Zone a Mortoniceras hugardianum d’Orb. sp. V_= Zone a Hoplites dentatus Sow. sp. IV Zone a Hoplites (Leymeriella) tardefurcatus Leym. sp. III Zone a Douvilleiceras nodosocostatum d’Orb. sp. et Douv. Bigoureti Seunes sp. The Clansayes horizon (Kilian’s Zone 1, Jacob’s Zone III) is, therefore, added to the Albian. Jacob could not accept Barrois’ zone a Ammonites mammillaris because he considered that this form was equally abundant in the following horizon (i.e dentatus = interruptus Zone), mistaking forms such as Douvilleiceras clementinwm (d’Orbigny) for ‘Ammonites mammillaris’. So, he renamed the zone ‘Zone IV a Hoplites (Leymeriella) tardefurcatus’ (= Zone of Hoplites tardefurcatus and Hoplites regularis in Kilian). Kilian and Jacob correct the specific name of the interruptus zone to that of dentatus, but Jacob does not adopt the index Acanthoceras lyelli. When revising the section at Sainte Croix, Vaud, Switzerland, Jacob indicates (1908 ; 291) that Zone IV = I’ Albien inférieur, V = |’Albien moyen, and VIb = 1’Albien supérieur of Pictet & Campiche (1858). Jacob seems to have misread Jukes-Browne (1900) for it was not the term Gault that Jukes-Browne could not accept, but the term Albian in the sense of Barrois (Jacob 1908 ; 584). The re-inclusion of the Zone 4 Ammonites inflatus of Barrois (Kilian’s Zone 4, Jacob’s Zone VI) in the Albian, a return to d’Orbigny’s original definition in terms of lithology, removed the cause of Jukes-Browne’s objection to the term Albian. Neither Jacob nor Kilian accepted or even mentioned Jukes-Browne’s Zone of Ammonites lautus. This is understandable when one considers that they were strongly influenced by the succession in the Aube (1908 ; 547), with which Price & Delatour had given a completely inaccurate correlation of the beds at Folkestone IN THE ANGLO-PARIS BASIN 113 (1879 : 1880 ; 38-42). Moreover, the time span represented by Beds II to VII at Folkestone are represented in the Alpine area of France and adjoining Switzerland by very condensed deposits in which many horizons are not represented at all. At that time the only description of any detail of the section near Wissant was a poor one by Barrois (1879 ; 27-28) an abridged version of which was given by Jukes-Browne (1900 ; 378-381). Although Barrois had been unable to recognise exactly at Wissant the equivalents of the beds numbered by Price at Folkestone, Price stated definitely (1879 : 1880 ; 34) that they held good at Wissant. So, according to Price, the numbered sequence at Folkestone could be correlated not only with the Aube but also with Wissant. The gravity of this error can be judged from the stratigraphical account of the French sections given above (p. 80) where it is apparent that a major part of the Middle Albian sequence in the Aube is not represented at Wissant and vice versa. Although Jukes-Browne agreed with Barrois that the exact equivalents of the Beds at Folkestone could not be recognised at Wissant, he perpetuates Price & Delatour’s erroneous correlation between Folkestone and the Aube (1900 ; 388-9). There is no doubt that this strongly influenced subsequent work on both sides of the Channel, and this is the reason why French geologists of that period considered that the beds at Folkestone included by Jukes-Browne in his Zone of Ammonites lautus were of the same age as part of the clays in the Aube included by them correctly in the interruptus (dentatus) zone. This led to the time spans, which I now label mammuillatum, loricatus and lautus Zones, being not recognised at all in Kilian or Jacob’s zonal schemes. The historical background to the zonation of the Middle Albian only will now be considered below. That of the Lower Albian has been dis- cussed by Casey (1961a ; 492-499) and the Upper Albian will be discussed elsewhere. In Germany the term ‘ Gault ’ included clays of Aptian as well as Albian age (see for example Kilian 1907-13). It had been divided into lower, middle and upper Gault within the first half of the 19th Century and the question of nomenclatorial priorities has been discussed by Spath (1942 ; 670-671). Stolley (1908 ; 246-7) recognised in the ‘Oberen Gault ’ of north Germany the zones already well established in France. The ‘Zone des Hoplites interruptus’ No. 6 is represented by the Minimus Tone and is followed above by the ‘ Zone der Schloenbachia inflata und Puzosia planulata’ No. 7 to include the Flammenmergel. Jacob’s scheme con- tinued to be used in France (e.g. Tomitch 1918, Ciry 1927, Houdard 1940). Spath’s work on the classification of the Albian commenced with the following arrangement (19214, 32). Gault Up. & Mid. Albian Zones 7 & 6 of Stolley (1908) Mammillatus Bed Lower Albian eS tt se (LQOS) Later in the same year, Spath amplified this classification (I92Ib ; 311). Upper Albian Hor. IX—XIII (Folkestone) Hor. 7 (Stolley) (Upper Gault) VI (Jacob) Middle Albian Hor. I-VIII (Folkestone) Hor. 6 (Stolley) (Lower Gault) V (Jacob) mammillatum bed The mammuillatum Zone is, therefore, now included in the Middle Albian. In 1922 H 114 MIDDLE ALBIAN STRATIGRAPHY Spath produced a scheme of ammonite horizons which foreshadowed the zonal scheme which appeared the following year (1922 ; 96). He was far too critical of the previous work on the Albian and certainly misread Jukes-Browne, and so in 1923 he dis- carded the broad zonal classification of previous workers in favour of the scheme shown in Table 2. This zonal scheme was strongly influenced by the sequence at Folkestone which Spath had examined in detail (1923a ; 73 : 1923b ; 4 : and see also 1923c). Unfortunately, in England the sequence between the ‘ mammillatus Zone’ and the ‘dentatus Zone’ was at that time very imperfectly known. The ‘ inaequin- odus Zone’ formed a very uncertain taxon, and the ‘ benettianus Zone’ was par- ticularly ill-founded for Spath had no idea of the exact stratigraphical position of the lyellu fauna (1923c : 142, see 1926b ; 422), and he was later to classify even high spatht Subzone sediments with that Subzone. De Rance had already used the term ‘benettianus Zone ’ in a different sense, and it is unfortunate that Spath ignored the sequence in the southern part of the Paris Basin. In effect he restricted the dentatus Zone to exclude much of what the French workers understood by this term. He also discarded Jukes-Browne’s lautus zone replacing it with zones of intermedius, delaruet and cornutus, but added a cristatus zone for Bed VIII and its lateral equivalents. It was unfortunate that this scheme should have been presented before Spath had fully studied the species he had used as indices. In the following two years he had to alter this zonal scheme (1924 ; 505 : 1925b ; 31-36), and the year after (1926b ; 421-2, 425) saw the extensive modification shown in Table 2 (p. 116). In 1926 Spath first renamed the lower part of his cornutwm Zone, the Zone of Euhoplites alphalautus (1926a ; 154 footnote 1), and then later recognised that this species was a form found in the varicoswm Zone. The major change in the scheme given by him later that year (1926b ; 421-2, 425) was the relegation of his zones to the rank of subzones in the Table on p. 421. However, the presentation shows several inconsistencies for he refers to these subzones in the text as zones. In the table he groups the subzones into the ‘ old zones’ which are in fact those used by Jukes-Browne, the names being corrected where necessary. Spath included the intermedius Subzone in the dentatus [olim interruptus] Zone, but Jukes-Browne had in fact included Bed II at Folkestone in his lautus zone. Spath recognised, however, that the zonal schemes which had been used in Europe were of provincial value only, and this was a significant step forward. The zonal scheme was further modified during the course of publication of successive parts of Spath’s Monograph, and one saw the firm readoption of the broader zones. He formally presented the various emendations to his earlier scheme in I94I (1941 ; 668) and discussed them briefly the following year (1942 ; 671-673) : these are given in Table 2. His ‘ zones’ of 1923 are now emended and reduced to the status of Subzones which are grouped into three Zones. The mammillatum Zone is much the same as that of Barrois and Jukes-Browne, however, the dentatus and lautus Zones do not correspond with the views of earlier workers despite Spath’s comment (1942 ; 672 footnote 3). Is the arrangement given by Spath an improvement ? The junction between the dentatus and lautus Zones was placed by Spath at a level where there is no significant change in the fauna and the arrangement is quite arbitrary. The older zonal grouping of French and English workers such as Barrois and Jukes- IN THE ANGLO-PARIS BASIN II5 Browne was based on a comprehensive knowledge of all the sections then available. Even if they did not consider the detail essential to modern work to be of great importance, they possessed a broader picture than many later workers, some of whom had never examined the sections in the country separated from them by the Channel. Superficially Spath’s early stratigraphic work appears to have given far greater precision to the zonation of the Albian, but this was not so. His zonal scheme was introduced without sufficient initial research and suffered greatly by the early need for radical alteration, and in the end his zonal boundaries were ill-chosen. He appears not to have examined the French sections (1943 ; 722-3), which is most unfortunate as it is absolutely essential to have some first-hand knowledge of them. There is no question, however, of the immense value of his contribution. Without his work on the Albian ammonites the progress made in the study of the stratigraphy during the last 25 years would have been very slow indeed. Breistroffer (1947) made the first revision to Spath’s zonal scheme in an important paper comparing essentially the French with the English succession. In this work he includes the mammullatum Zone in the Lower Albian and the cvistatum Subzone in the Upper Albian (1947 ; and Table 2 herein). Casey (1950 ; 270) noted Breistroffer’s reading of the mammillatum Zone but followed Spath in including it in the Middle Albian. Khan (1952 ; 73) produced a useful emendation when he included the subdelaruet Subzone in Spath’s sense, in the dentatus Zone ; thus placing the junction between the dentatus and lautus Zones at a point where there is some significant change in the ammonite funa. Casey, however, again followed Spath in terminating the dentatus Zone at the top of the niobe Subzone (1954a ; 264). Milbourne (1956 ; 241) could not accept a separate subdelaruei Subzone in Spath’s sense. He included the lower part of Bed IV and its lateral equivalents in the miobe Subzone, and the upper nodule bed of Bed IV and its lateral equivalents in the lautus-nitidus Subzone recognising that these probably fell within a distinct Subzone. The writer in 1958 reviewed briefly the zonal scheme of the Middle Albian, placing the zonal boundaries at levels where significant changes in the ammonite fauna occurred (1958 ; 160-164). At the same time I drew attention to the difficulties that existed in accepting Breistroffer’s emendations of Spath’s zonal scheme for the dentatus and lautus Zones ; except for the position of the cristatwm Subzone, these have not changed. Subsequently, I proposed formally that the time span repre- sented at Folkestone by the upper nodule bed of Bed IV and the basal few inches of Bed V and their lateral equivalents be recognised as the Subzone of Euhoplites meandrinus (1960 ; 373, 376). The zonal grouping suggested by the author in these two papers is shown in Table I, p. Io. In 1961 Casey produced his important revision of the zonal scheme for the Aptian and Lower Albian (1961a ; 492-499). He now follows Breistroffer in including the mammillatum Zone in the Lower Albian with the exception of Spath’s inaequinodum Subzone. For this Subzone he proposes a new index, Hoplites (Isohoplites) eodentatus, and includes it in the dentatus Zone of the Middle Albian, pointing out that this species is the most characteristic ammonite at this horizon in England and France. The division between the mammillatum and dentatus Zones and thus the Lower and Middle Albian now falls at a distinct change in the ammonite fauna. MIDDLE ALBIAN STRATIGRAPHY 116 tamjapopnasd -snuniyauag aygods -snyqpyuap snayamim -snyvyuap xovavAg -SnUpamMAgqur [aqowu] wnsojnurds vanawjapqns wnyojsoainba _snpyse vanavjapqns -snpyu wsa1nwp souozqns SOU0Z Lb61 JoyoIMstoig ayuout WNnywoY UMD wunpoummbanur SNUDIJGUAQ uyjaanuog -smyvyUuap snipamasaqur aqowu Lananjapqns SNPYWU-snqnv} wsaunwp WN4YDIS1AI seuozqns €r6r yyeds snyvquap smyny] souoz WNDU SIDI WnwY UMD wunpoummbanur snpoumbavur snunyyauaq | snunyyauag snqojuap snqvquap Sein snupausaqur | snypamaaqur aqoiu ranawjap 1anavjap eee ae + ie ee SNANUAOI wsa1nwp wnqyoysts2 | SN4D4S1AI souozqns , S8U0Z PIO , SOuO07Z qgz61 yyeds €z6r yyeds ‘LPOI pue £261 uaaMmyzoq URIGIY IPP 94} JO UOIeUOZ oY} UT seSueYyD Z ATAVE ueydoyH ueyydoyeuy IN THE ANGLO-PARIS BASIN 117 Milbourne (1963 ; 58) places the division between the dentatus and lautus Zones above his niobe Subzone (which also includes the swbdelarue: Subzone of Spath in part). He finds my Subzone of Euhoplites meandrinus unacceptable and substitutes for it a Subzone of Dimorphoplites doris and Euhoplites neglectus. He places the subzone in the /autus Zone and so once more the boundary between the two zones is placed at a level where there is no significant change in the ammonite fauna. The differences of opinion between Milbourne and myself led to a skilful review of the zonal scheme by Hancock (1965). Unfortunately two errors were overlooked when preparing Table I of Hancock’s paper (1965 ; 245). The eodentatus Subzone was not recognised by me in 1958 but by Casey (1961), and Spath’s lautus-nitidus Subzone did not include the time span referred by me to the meandrinus Subzone. The meandrinus Subzone formed part of the swbdelaruet Subzone in Spath’s sense and it is important to make this point absolutely clear. In 1963 a colloquium on the Lower Cretaceous was held in France ; two very important papers being contributed by P. & J.-P. Destombes, and Breistroffer, on the zonal scheme of the Albian. These were published in 1965. P., & J.-P. Des- tombes propose the following arrangement (1965 ; 266). Zone Sous-zone Localité-type 2—Lyelliceras lyelli et La Vendue-Mignot Hoplites benettianus LYELLICERATIEN 1—Tegoceras camatteanum Cotes Noires de Moeslains Isohoplites eodentatus niv. 5 This proposition is interesting as it shows in the case of Lyelliceras lyelli an independent return to the older view expressed by Barrois, Price, and Kilian, al- though it should be noted that Collignon has also used this index (1963 ; 2). P.& J.-P. Destombes use a hemeral name for the zone. The use of these terms particu- larly by Spath and Breistroffer, is not supported here for they are far too nebulous to have any really precise application. Breistroffer’s paper (1965 ; 311 & table) presents an emendation of his zonal scheme of 1947 and he accepts P. & J.-P. Destombes subzonal arrangement for the basal part of the Middle Albian. The scheme given by Collignon (1965b) is quite unacceptable. The history of this zonal scheme, like that of any other, has been one of progressive refinement as knowledge of the succession has improved. Unfortunately, the Albian in particular has suffered greatly because of arbitrary decisions concerning the fixing of ammonite zonal and subzonal boundaries. These boundaries have been placed sometimes without sufficient initial research and have been upheld later purely on rather dubious ‘ historical’ grounds ignoring whether or not there is a significant change in the ammonite fauna. A zonal scheme must remain sufficiently flexible to take account of new discoveries and better developed sequences. To bang in a ‘golden stake’ at a convenient level in a so-called permanent type-section might help the theorist but in reality it only hinders progress towards accurate international correlation, and the knowledge of events in the evolution of the Earth that will stem from it. 118 MIDDLE ALBIAN STRATIGRAPHY (B) The Zonal Scheme of the Middle Albian in the Anglo-Paris Basin (i) DEFINITION OF THE BASE OF THE MIDDLE ALBIAN Towards the top of the mammillatum Zone (puzosianus Subzone) in the Anglo- Paris Basin the ammonite genus Pseudosonneratia (s.s. non Casey!) develops as a minority element subordinate to such hoplitid genera as Protohoplites s.s., P. (Hem1- sonneratia), Otohoplites, and Sonneratia as well as the common element consisting of Douvilleiceras, Beudanticeras etc. The lyelliceratids are represented by very rare specimens of Tegoceras. Pseudosonneratia of the pusosianus Subzone is the direct forerunner of the simple- ribbed non-lautiform species of Hoplites of the dentatus group. Casey (1954b ; 112, 1g61a ; 599) has separated off those species which are transitional between these two genera as a Subgenus Hoplites (Isohoplites). They are characterised by a partial interruption in the strength of each rib along the siphonal line as it sweeps across the venter, but no general en echelon offsetting of the ventro-lateral rib terminations occurs although the tendency towards this is often apparent. Casey has demon- strated that Hoplites (Isohoplites) characterises an horizon above the development of the typical mammuillatwm Zone fauna and corresponds approximately to Spath’s inaequinodum Subzone (Casey 1961a ; 498 : Spath 1923b ; 73). He included the Subzone in the dentatus Zone and subsequent work in France (P., & J.-P. Destombes 1965 : and herein) and England support this reading. The junction between the mammuillatum Zone and the eodentatus Subzone has not yet been seen in an uncondensed sequence in England. Sediments spanning the zonal boundary have, however, been exposed in France at St. Martin in the Pays de Bray (p. 100) andat Les Cotes Noires in the Haute Marne (p. 91). At both localities there is a marked change in the ammonite fauna with the virtual disappearance of Otohoplites at the top of the mammullatum Zone, and the appearance in bulk of Hoplites (Iso- hoplites) at the base of the eodentatus Subzone above. In England the available exposures of the sequence at this level show only condensed phosphatic nodule beds in which the sudden change in the character of the ammonite fauna is probably accentuated. The base of the Middle Albian in the Anglo-Paris basin is marked, therefore, by the appearance of the genus Hoflites, and as is shown below by the appearance of Lyelliceras. 1 Dr. P. Destombes has collected a very fine ammonite fauna from two localities in the Bois de Perchois, Aube, which I have visited in company with him. It is apparent from the material he has shown me that Pseudosonneratia iserensis figured by Casey (1965 ; 541 text-fig. 203e, f) is associated in a very little condensed sequence—the ‘ Red Bed ’—at Perchois Ouest with species of Cleoniceras (Neosaynella) and Cleoniceras s.s., indicating a flovridum Subzone age. It contains species of Otohoplites earlier than any yet known in England, showing morphological gradations to the Pseudosonneratia-like forms which accom- pany them in the same bed. The collection also contains species of Sonneratia with distinct hitchini Subzone affinities, although higher in the succession, as well as Douvilleiceras, Beudanticeras and Pro- tanisocevas. The fauna of Perchois Est, although preserved in a similar manner, occurs higher in the mammillatum Zone sequence. The very important fauna obtained from these two sections is to be described in due course by Dr. P. Destombes (see also Destombes 1965). The area is also of interest in that at Perchois Ouest the grey clays above the ‘ Red Bed’ contains an ammonite fauna of distinct tethyan aspect. IN THE ANGLO-PARIS BASIN 119 (ii) THE SUBZONAL SEQUENCE (Table 1, p. ro) (a) Subzone of Hoplites (Isohoplites) eodentatus Recognised by Casey (1961a ; 498), although few details were given on that occasion, this index replaces the Subzone of Douvilleiceras inaequinodum of Spath (1923a ; 4 : 1923b ; 73 : 1941 ; 668). In England, the Subzone is represented in a fossiliferous uncondensed state in the Isle of Wight (p. 52) and at Okeford Fitzpaine, Dorset (54). Elsewhere, the known sections exhibit either unfossiliferous sediments which probably represent this time span, or rvemanié phosphatic nodule beds. Future deepening of the section at Small Dole, Sussex (p. 35) and at Badbury Wick, Wilt- shire (p. 61) may provide a fossiliferous little-condensed sequence from which a direct comparison can be made with the succession at St. Martin (p. 100). Maurupt (p. 89) and Les Cétes Noires (p. 91) in France. Nowhere in England are the sections at the outcrop in this subzone particularly fossiliferous. In England, the ammonite fauna consists essentially of species of Hoplites (Iso- hoplites) of which H. (I.) eodentatus is typical. It is necessary to bear in mind that the tendency to produce the peripheral rib pattern of a typical Hoplites (H.) men- tioned already, can be so well advanced that a fragment or even a complete individual would have to be referred to Hoplites (H.). This fact alone shows the artificial nature of the subgenus Isohoplites. However, these are associated with species in which the Pseudosonneratia ventral aspect is still well developed. Apart from the forms derived from Pseudosonneratia, there are other Hoplites derived from Otohoplites and possibly Protohoplites, and in fact rare specimens of Otohoplites still occur. The associated ammonites include Beudanticeras such as B. laevigatum, B. albense, and B. santaecrucis, together with Douvilleiceras spp. including D. inaequinodum. Lyelliceras of the camatteanum type, which stands rather in the same relationship to Tegoceras on the one hand and Lyelliceras of the lyelli type on the other, as does Isohoplites in the hoplitinids, is a great rarity in England. In France it is a reason- ably constant and characteristic companion of Hoplites (Isohoplites) and the other ammonites mentioned above, and this has led P. & J.-P. Destombes to recommend that the Subzone be defined as that of Tegoceras camatteanum and Isohoplites eodentatus (1965 ; 265-6). They indicate a type locality, Les Cétes-Noires prés de Moeslain, where the subzone is represented by clays in an apparently unbroken sequence from the top of the mammillatum Zone to the base of the lyelli Subzone. In the lower clays classified with the eodentatus Subzone there is the association of Hoplites (Isohoplites) eodentatus and Lyelliceras camatteanum as there is also at Maurupt and St. Martin. If one wishes to use a double index then this emendation proposed by P. & J.-P. Destombes should be adopted. However, as H. (I.) eodentatus is common to this time span throughout the Anglo-Paris basin, the writer employs this index only. (b) Subzone of Lyelliceras lyelli P., & J.-P. Destombes (1965 ; 265-7) have formally proposed that the benettianus Subzone in Spath’s sense should be redefined as the Subzone of Lyelliceras lyelli & Hoplites benettianus. So, the tentative suggestion of Barrois, the bald statement of 120 MIDDLE ALBIAN STRATIGRAPHY Price, the formal proposal of Kilian and the employment of the name by Collignon (1963 ; 2) given precision by P., & J.-P. Destombes, has at last taken root. H. (H.) benettianus is not a satisfactory subzonal index for in the strict interpretation it may be restricted to only a comparatively narrow horizon within the Subzone that it is supposed to represent. They have proposed a type locality for this Subzone, the Tuilerie Clerc at La Vendue-Mignot, Aube (p. 95), where the Lyelliceras fauna is con- sidered to be in the pure state without risk of contamination (in terms of collecting fossils that is). In fact the section does not show the relationship between either the eodentatus Subzone below or the spatht Subzone above, and there are other objections already mentioned. The benettianus Subzone was defined without precision by Spath (1923a ; 4, 1923b ; 73, 1926b ; 422), and was used by him for a range of sediments some of which are truly lyelli in age but others have subsequently proved to be of spathi age. It would be far more satisfactory if the proposal of P., & J.-P. Destombes were adopted modified to a single index of Lyelliceras lyellt. In France, the finest section now available in sediments of this Subzone is certainly that of Courcelles prés Clérey, Aube (p. 91), although that at Les Cétes Noires is probably the most completely displayed in terms of sediments. The best develop- ment seen in England was exposed at the Horton Clay pit near Small Dole, Sussex (p. 35). A comparison of these two sections brings out the nature of the ammonite fauna and the differences to be found between them. Lyelliceras camatteanum and its related species of the eodentatus Subzone is connected with Lyelliceras lyelli by a series of morphological transitions. Intermediate forms such as Lyelliceras pseud- olyelli (Parona & Bonarelli non Spath), Lyelliceras huberianum (Pictet) and L. hirsutum (Parona & Bonarelli) form such transitional species. These show the transition from the extreme en-echelon arrangement of the ventro-lateral rib termin- ations and non-tuberculate siphonal line characteristic of Tegoceras, to the single ribs commencing at the umbilical margin and sweeping without break straight across the periphery and bearing mid-lateral, ventro-lateral and siphonal clavi typical of Lyelliceras lyelli. These transitional forms occur right at the base of the lyelli Sub- zone both at Courcelles and to a limited extent at Small Dole, and on balance it seems that the time span in which they existed was of comparatively short duration. Un- condensed basal /yelli Subzone sediments are also apparently well developed in the Céte d’Or (e.g. Ciry 1927 : Ciry, Rat, Malapris & Nicolas 1965). It is apparent that ecological conditions have a marked effect upon the ammonite fauna. In deposits of the lyelli Subzone containing a benthonic fauna, the hetero- morph ammonites Protanisoceras (P.) barrense and P. (P.) alternotuberculatum are common (e.g. Small Dole, and Courcelles) and are as equally characteristic of this time span as is Lyelliceras lyelli. Where no benthos is present, or it is very reduced in numbers, the heteromorph ammonites are absent or very rare (e.g. the Isle of Wight). Lyelliceras lyelli is also affected by ecological conditions in that in beds containing abundant Hoplites (H.), Lyelliceras is not common. Casey has already noted the tendency to mutual exclusiveness between the earlier members of these two families (1957 ; 43-44), although this could in part be due to the hoplitids being able to withstand more adverse conditions in the seas of that time. However, the IN THE ANGLO-PARIS BASIN 121 distribution of Beudanticeras laevigatum, B. sanctaecrucis and B. albensis is not affected by either of these two factors. In fact the lyelli Subzone may be recognised in areas in which sea-bottom conditions produced a sulphide facies in the sediments, by the association of Hoplites (H.) spp. and these three species of Beudanticeras. The distribution of Douvilleiceras is also not constant. It is rare at Small Dole, although very common at the top of the lyelli Subzone at Courcelles. It was also not un- common in Bed 14 at Shere (Owen 1963< ; 42). The uppermost part of the lyelli Subzone and its junction with the overlying spathi Subzone cannot alone be determined by the abrupt disappearance of Lyelliceras lyellv. In England, at Small Dole, Sevenoaks (p. 23), and Westerham (p. 31), and at Courcel- les (Aube), there are clays just below the spathi Subzone which still contain lyelli Subzone species of Beudanticeras, Douvilleiceras (Courcelles only), and Protanisoceras (P.), but Lyelliceras is absent. It is recommended that these sediments be included in the lyelli Subzone for the significant change in the ammonite fauna occurs at the top of them where all the non-Hoplites (H.), lyelli Subzone ammonite species vanish abruptly from the sequence. In the English and French sections mentioned here there is no apparent break in deposition and no change in facies. Pvrotanisoceras (P.) still occurs in the spathi Subzone but it is very rare, and, in effect, the heteromorphs are almost exclusively species of Hamites (H.) with subordinate Metahamites. There is no major change in the species of Hoplites (H.) in the transitional period between the lyelli and spatht Subzones. The transitional sediments at the top and bottom of the lyell1 Subzone are of no great thickness in well developed sequences. Even slight condensation produces an apparent sharp change in the ammonite fauna at the subzonal boundaries. (c) Subzone of Hoplites (Hoplites) spathi H. (H.) spathi in its typical form occurs in this subzone but it is not very common, although there is no dearth of closely related forms. It is possible that Spath selected this species (1941 ; 668 : 1942 ; 672, under the preoccupied name bonarellit) because in terms of ornament it stands mid-way between the more discoidal finer ribbed species of the dentatus type and the inflated coarsely ornamented forms of the maritimus-rudis group. The name dentatus-spathi Subzone is in any case too well established in the recent literature both sides of the Channel to justify altering it, except to reduce it to a single index of H. (H.) spathi. The Subzone is well developed in England and the section at Small Dole is par- ticularly important as it shows in a very fossiliferous little condensed sequence the junction with the lyelli Subzone below and, albeit imperfectly, the intermedius Sub- zone above. In France, the junction with the lyelli Subzone is seen in an uncon- densed sequence at Courcelles, and the junction with the intermedius Subzone again in an uncondensed sequence at Revigny-sur-Ornain (p. 88). The ammonite fauna consists very largely of species of Hoplites (H.) of which the general evolutionary characteristics of stratigraphical value have been given by me (Owen 1963a ; 49). The very small percentage minority element in the fauna provides a good list of genera and species (p. 152) some of which are of value in correlation with other faunal provinces. 122 MIDDLE ALBIAN STRATIGRAPHY The division between the /yelli and spathi Subzones has been discussed above. The sediments representing the transitional period between the spathi and intermedius Subzones do not contain ammonites in the area of the Weald except at Petersfield (p. 34). At present it cannot be demonstrated in any one section in England, how- ever, the section at Osmington (p. 51), Dorset, and Caen Hill, Devizes (p. 60) show the extreme top of the spathi Subzone and the extreme base of the intermedius Sub- zone respectively. Bed 2 at Osmington contains abundant high spathi Subzone Hoplites (H.) together with rare early forms of Anahoplites of the intermedius group such as A. osmingtonensis and A. grimsdalei spp. nov. In Bed 7 at Caen Hill, Hoplites (H.) has become very subordinate to slightly later forms of Anahoplites such as A. evolutus which are in turn earlier than Anahoplites intermedius and its con- temporaries. A. evolutusis also known from Bed C at Hunstanton. These sediments containing A. evolutus are here considered to mark the base of the intermedius Subzone. In France, fragments of Anahoplites osmingtonensis and A. evolutus occur in Bed 4 at St. Florentin (p. 97), a phosphatic nodule bed containing en melée material derived from both the spathi and intermedius Subzones. At Revigny-sur-Ornain (p. 88) these transitional sediments are uncondensed but the ammonites are mainly crushed flat. At Wissant sediments deposited during this period have not yielded ammonites. There is no difference between this interpretation of the spathi Subzone and the views of French geologists (e.g. Breistroffer 1965 ; 313). From this account it is now obvious that the parochial view expressed by Milbourne (see Hancock 1965 ; 246-7), fixing the top of the spathi Subzone at an horizon of condensation in a comparatively small area of the outcrop in the northern Weald, is totally unacceptable. The record of Anahoplites intermedius a foot or two above the spathi nodule bed at Folkestone (Bed I (vi) ) by Casey (in Hancock 1965 ; 247) is here considered to be a misidentifica- tion of the finely-ribbed H. (H.) dentatus densicostata Spath which is just as common in the higher part of the Subzone. (d) Subzone of Anahoplites intermedius Although there is some condensation at Folkestone, this section (p.14) provides the best sequence yet known in this Subzone recognised by Spath in 1923. The sequence at Small Dole is the least condensed and also shows, albeit imperfectly, the junction with the spathi Subzone below, and also the junction with the nzobe Subzone above ; however, the fauna is crushed flat. The junction with the sfatht Subzone has been discussed above. The lowest part of the Subzone with Anahoplites evolutus has not yet been discovered in the Weald and so at Folkestone the earliest intermedius Sub- zone sediments containing ammonites yield Anahoplites intermedius and A. praecox. In France the section at Wissant shows an imperfect development of sediments representing this Subzone, but at Revigny-sur-Ornain, and at Courcelles the lower part is well developed. . The characteristic ammonites of this time span are the group of Anahoplites typified by A. intermedius. The ammonite fauna of the Subzone as a whole is more diverse than that of the spathi Subzone below. Hoplites (H.) is greatly subordinate to the other genera, but the group which had produced rare Euhoplites by the top of eS IN THE ANGLO-PARIS BASIN 1736) the spathi Subzone is well represented by forms such as E. loricatus, E. microceras, E. subtabulatus and E. priceit. Early forms of Dimorphoplites including D. niobe (praemutation) occur sparingly, and some of these show a tendency to the lautiform ribbing not generally developed again in the genus until the meandrinus Subzone. Heteromorphs are not uncommon and consist not only of Hamites (H.) spp., but also of species of Protanisoceras (Heteroclinus). The early binneyitid Falciferella mil- bourne: can be abundant at certain horizons. Apart from the endemic forms, there is a much rarer element represented by specimens of Uhligella, Tetragonites, Des- moceras, Eubrancoceras and Pseudhelicoceras (e.g. P. subcatenatum Spath.) The upper limit of the Subzone is marked by the quite sudden decline of Ana- hophites of the intermedius group, which do not extend into the miobe Subzone above. (e) Subzone of Dimorphoplites niobe The Subzone was recognised by Spath (1924 ; 505), it having previously formed part of his intermedius Zone (1923a, b). It has been considered to be of local value (Spath 1942 ; 672) but in fact it is of widespread occurrence. Sediments of this time span are relatively uncondensed at Folkestone and to a lesser extent at Small Dole. Elsewhere in the Weald the sequence is somewhat condensed, where indeed it has escaped basal Upper Albian planation. Outside the Weald, it is developed in the Leighton Buzzard district. In France, the Subzone may be developed at Wissant (p. 83), but the only locality at which it can be proved with certainty is Cauville, Seine Maritime (p.107). The restricted development of the miobe Subzone led Breis- troffer in effect to include it in the imtermedius Subzone (1947 ; 44, 1965 ; table opposite p. 312) but his view was probably also influenced by Spath (1942 ; 672). The ammonite fauna is a curious one in that it has no species restricted to it, yet it is distinctive. Anahoplites intermedius and its allies have gone, and Dimorphoplites niobe, A. planus and A. splendens are the characteristic species. The upper limit of the Subzone occurs immediately below the appearance of Mojsisovicsia in the sequence. (f) Subzone of Mojsisovicsia subdelaruei Originally indexed by Spath (1923a ; 4, b ; 73) using ‘ Dipoloceras’ delaruei. He realised later that this species did not occur in this time span, and it has been found subsequently in the spathti Subzone. The Subzone as originally defined included sediments now classified with the meandrinus Subzone. The Subzone is represented by uncondensed deposits at Ford Place, Wrotham (p. 22) and at Sevenoaks (p. 25), but elsewhere in England where deposits of this age are preserved they are condensed. In France, they are known only in a condensed state (e.g. Bed 11 at Wissant). Apart from the species of Mojsisovicsia, a genus which last made its appearance in the Anglo-Paris basin in the spathi Subzone, and which in the swbdelaruet Subzone shows marked evolutionary changes, the hoplitinid fauna shows more diversity of form than in the niobe Subzone below. Mojsisovicsia subdelarue: appears at the base of the Subzone and evolves to M. remota at the top. The occurrence of Dimor- phoplites mobe led Milbourne to unite this time span with the miobe Subzone (1956 ; 241, 1963 ; 64), but on balance this incursion of keeled ammonites into the Anglo- 124 MIDDLE ALBIAN STRATIGRAPHY Paris basin dictates that it be kept separate. The species of Ewhoplites show little difference to those of the niobe Subzone below, but Dimorphoplites commences to differentiate towards the forms seen in the meandrinus Subzone above. The upper limit of the Subzone coincides with the last appearance of M. remota. However, Mojstsovicsia is not at all common at this height and it is necessary to use the grade of development shown by the species of Euhoplites and Dimorphoplites at the base of the meandrinus Subzone, discussed below. (g) Subzone of Euhoplites meandrinus This time span, included by Spath in his subdelaruei Subzone, was indexed by the writer (Owen 1960 ; 373, 376). Its separate nature was recognised by Milbourne (1956 ; 241), who included it provisionally in the mit#idus Subzone, and by the author (Owen 1958 ; 162). Unfortunately, there is an error in Hancock (1965 ; 245 Table I) for this Subzone was not included by me in the mtidus Subzone, that is, in the basal Subzone of the Jautus Zone as restricted by me in 1958. Milbourne (1963 ; 65) indexed this Subzone with his ‘ species’ Euhoplites neglectus (which on examination of the type material proves to be a synonym of EF. meandrinus) together with Dimor- phoplites doris. My objections to this emendation were set out in Hancock (1965 ; 247) and this clash of opinion led to a mistake in the zonal scheme given by Kaye (1965 ; 220). The Subzone is characterised by EF. meandrinus and closely related forms such as E. cantianus, E. loricatus (late mutation), and E. beaneyi which still possess the deeply sulcate venter characteristic of the genus in the preceding subzones. The late mutation of E. subtuberculatus tends to show the development of the channelled venter characteristic in the lautus Zone on its outer whorl, but the inner whorls are still sulcate. The pattern of ribbing on most of these species is transitional to that of the typical Jautus Zone species. Dimorphoplites has become more diverse in form and apart from the typical meandrinus Subzone species such as D. doris and D. pinax, there are the early mutations present of the species which occur commonly in the lautus Zone above but they are greatly subordinate in numbers. Mojsisovicsia is absent from this time span. In England, the meandrinus Subzone is present in an uncondensed sequence at the Horton Clay Pit, Small Dole (p. 40). At the Sevenoaks Brick Works (p. 25) and further east in Kent, the sediments are condensed to a variable extent. Its known representation is confined to eastern England. In France, the only locality at which the Subzone is known to be represented at this time is at Wissant in Bed 11 which also contains material derived from subdelaruei Subzone sediments and mitidus Sub- zone sediments as well. At Small Dole, and at Ford Place, in particular, the sudden change from a sulcate to a channelled venter in the species of Euhoplites can be well seen in sediments which are uncondensed. This marks the base of the overlying mitidus Subzone. (h) Subzone of Euhoplites nitidus Spath originally included Beds V—VII at Folkestone in a zone of Dipoloceras cornutum (1923a ; 4, b ; 73) but having realised the rarity of that species he divided IN THE ANGLO-PARIS BASIN 125 this zone into two ; the zone of Ewhoplites alphalautus (1926a ; 154 footnote I) to include Beds V and VI, and that of Anahoplites daviesi to include Bed VII (see also 1925b ; 34-35). Within a few months he realised that E. alphalautus was a form of the varicosum Subzone, and substituted for it Ewhoplites lautus and E. nitidus (1926b ; 425). Breistroffer (1965 ; table opp. 312) has grouped the mtidus and daviest Sub- zones as Subzone of mitidus + cornutum + daviesi. This view is probably influenced by the section near Wissant where the daviest Subzone was thought to be present, but where it is now known to be absent (p. 85). In England, the best known development is at Folkestone where the relationship with the meandrinus Subzone below and the daviesi Subzone above is well seen (p. 15). In France, the Subzone is well represented at Wissant but the sediments there are marked by erosion levels at the base and the top (p. 84). The Subzone is not known to be represented elsewhere in France at this time. The base of the Subzone is marked by the general adoption of a channelled venter by the various species of the genus Euhoplites. The ammonite fauna of the Subzone has been discussed by Owen (1958 ; 154) and Hancock (1965 ; 246) and there is nothing further to add except that the top of the Subzone is now drawn at Folkestone at the level within Bed VII immediately below the first appearance of Anahoplites daviesi in the sequence. (i) Subzone of Anahoplites daviesi This Subzone recognised by Spath (1925b ; 35, 1926a ; 153-4) is characterised by Anahoplites of the daviesi group. There is virtually no difference in the accompany- ing ammonite fauna in England, but these very characteristic species of Anahoplites have a wide geographical range in this time span, and on this point alone the Subzone should remain separate from that of FE. mitidus. Breistroffer’s grouping (1965 ; table opp. 312) is not acceptable, and the British reading should be adhered to (e.g. Owen 1958 and Hancock 1965 ; 245, 246). The Subzone is best developed at Folkestone although it is present in uncondensed sediments elsewhere in Kent and Sussex (Ringmer). However, at Folkestone there are clays representing horizons higher than any known elsewhere outside the U.S.S.R. Even at Folkestone the top of the clays of Bed VII representing this Subzone are planed-off and the basal nodule bed of Bed VIII contains material of late daviesi Subzone age. At Wissant, the lower part of the cristatum Subzone (the partial equivalent of Bed VIII (i) at Folkestone) is represented by clays. Unfortunately these rest non-sequentially upon sediments of mitidus Subzone age (p. 85) and neither at Wissant nor elsewhere in France at this time have sediments of daviest Subzone age been proved. The development of the Subzone in Russia is mentioned later (p. 132). The upper limit of the Subzone can, however, be determined by reference to Bed 12 (v) at Wissant which contains no Anahoplites of daviesi type but in which Dipoloceras bouchardianum and Beudanticeras beudanti make their appearance marking the base of the cristatwm Subzone. In this bed also there occurs the morphological transition from Inoceramus concentricus to the shell form I. sulcatus (p. 85). 126 MIDDLE ALBIAN STRATIGRAPHY (iu) THE POSITION OF THE SUBZONE OF DIPOLOCERAS CRISTATUM The junction of the Lower with the Upper Gault at Folkestone is marked by two seams of phosphatic nodules separated by a few inches of clay (p. 15). This junction bed (Bed IV of De Rance 1868, and Bed VIII of Price 1879, 1880, Jukes-Browne 1900 and subsequent workers) has always been included in the Lower Gault. However, it has long been recognised that the fauna is a transitional one containing elements characteristic of the beds below and above. The bed formed the zone of Ammonites beudantii of De Rance, and that of Ammonites cristatus of Price. Jukes-Browne (1900 ; 45) did not include the time span represented by Bed VIII in his zone of Ammonites lautus. Spath, however, placed his cristatwm ‘zone’ in the Middle Albian (1923a, b) and later relegated it to subzonal rank and included it in the lautus Zone in his sense (1926b ; 425). This classification has been followed by later Eng- lish workers (e.g. in Hancock 1965 ; 245, 246). Breistroffer (1947 ; 48, 68) included the Subzone in the Upper Albian where it stood in isolation. The author stated that more research would have to be carried out before a final decision could be made on the position of the cristatum Subzone (1958 ; 164). However, in the meantime, Breistroffer’s recommendation (see also 1965 ; table) has been accepted by other workers such as Collignon (1963 ; 2) for the sequence in the Malagasy Republic, and Young (1966 ; 15) for the succession in Texas, and in England by Melville (in Smart et al., 1964 ; 7). Although Bed VIII contains a fauna which on balance links it with the Upper Albian, its lower nodule bed includes an important Middle Albian element derived from sediments of daviest Subzone age. One of the principle objections to placing the cvistatum Subzone in the Upper Albian is that hitherto it has meant placing the Middle-Upper Albian junction at a level of erosion. However, it is now known that the basal part of the cristatum Subzone is represented in an uncondensed sequence in Bed 12 (v) near Wissant. This fact removes any objection that the writer might formerly have held against placing the Subzone in the Upper Albian, and I now recommend that it be included in the Upper Albian to form the basal Subzone of the inflatum Zone. In Bed 12 (v) at Wissant we can see the incoming of a basal Upper Albian fauna in an uncondensed sequence (p. 85). The change in Inoceramus from a concentricus to a sulcatus form has already been mentioned. Beudanticeras beudanti appears together with D. bouchardianum. These forms are all known from Bed VIII (i) at Folkestone. Bed 13 at Wissant contains en melée material derived from the equivalent of Bed VIII (ii) & (iii) at Folkestone together with the lower part of Bed IX up to and including the horizon of Ewhoplites inornatus. In truth Bed 13 at Wissant forms the base of the Upper Gault in our sense as well as that of our French colleagues. However, they consider it to be the direct equivalent of Bed VIII, whereas it is in fact the product of one period of erosion which occurred at Wissant later in the crvistatwm Subzone, while at Folkestone there were essentially two phases of erosion at earlier dates within this Subzone. It has been, up to now, the view of our French colleagues that IN THE ANGLO-PARIS BASIN 127 all the Gault below Bed 13 of Destombes was of Middle Albian age, but it must now be recognised that Bed 12 (v) below is in fact of basal cristatum Subzone age. The fauna of the cristatum Subzone on balance, bearing in mind that a late daviesi Subzone element is present in Bed VIII (i), has its most important faunal link with the beds above rather than those beneath. The very characteristic lower Upper Albian bivalve form I. sulcatus develops in the basal part of the cvistatwm Subzone and ranges up to the top of the orbignyt Subzone. Towards the top of the Middle Albian daviest Subzone, extreme forms of Anahoplites of the daviest group occur which are close to, but still generically distinct from Epihoplites (including Metaclavites). At the same point in time species of Ewhoplites and Dimorphoplites modify towards those of the cristatum Subzone. The hoplitinids are almost completely dominant, the only Mojsisovicsiinid being Dipoloceras cornutum which is very rare. In the cristatum Subzone above we see the introduction of an important non-hoplitinid element in the ammonite fauna. In fact many of the subfamilies last well-represented in the Anglo- Paris basin in lyelli Subzone times appear once again in consort, and as before are subordinate to the hoplitinids. Euhoplites is well represented but the species are essentially different to those of the Middle Albian below, and are, moreover, more closely linked to those of the orbignyt Subzone. This genus survives until the awritus Subzone and it is interesting to find that a largely unfigured varicoswm Subzone fauna in the Leighton Buzzard area contains forms which are morphologically closer to those species of Bed V—VII at Folkestone than to those of Bed VIII. Dimorphoplites in the strict sense does not survive the cristatwm Subzone, its nitch being filled by Epihoplites (including Meta- clavites Casey). Itis quite possible that the ecologic factors which caused Inoceramus concentricus to develop the strengthened shell from of J. sulcatus, also brought about changes in the morphology of the endemic hoplitinids during the clearly unsettled physical conditions in the cristatwm Subzone sea. The non-hoplitinid element in the ammonite fauna is subordinate but highly characteristic of this Subzone and foreshadows the major development of the branco- ceratinid and mortoniceratinid ammonites which occurs at the base of the orbignyi Subzone in the sense used here. Hysteroceras is represented by H. pseudocornutum, H. capricornu, and H. simplicicosta, forms which are transitional from the earlier Eubrancoceras. An early mutation of H. orbignyz does in fact occur in the cristatum Subzone, but the only species of Mortoniceras known is M. rigidum although the generic position given it by Spath is uncertain. Dzpoloceras itself, the characteristic genus of this time span, probably gave rise to Mortoniceras but the picture is not clear at this time. The Lyelliceratidae is represented by Neophlycticeras which also ranges into the orbignyi Subzone but it is rare. Beudanticeras represented in the cristatum Subzone by the type-species B. beudanti and forms such as B. subparandieri, also continued on into the orbignyi and higher Upper Albian Subzones. The cristatum Subzone must also include the time span represented within the sediments of the basal part of Bed IX at Folkestone up to the level at which Hyster- oceras and Mortoniceras characteristic of the orbigny: Subzone suddenly became dominant. This just excludes the horizon of Euhoplites inornatus which is of wide- spread occurrence in England and forms a good marker for the base of the orbignyi 128 MIDDLE ALBIAN STRATIGRAPHY Subzone. The cristatwm Subzone as here defined, therefore, includes sediments grouped with the Upper Gault. As Breistroffer has pointed out (1947 ; 48-50), Dipoloceras cristatum and the other contemporary species of this genus are of widespread occurrence. They are known in sequences as far removed from each other as the Anglo-Paris basin, the Malagasy Republic and Zululand, Russia and Texas, that is, in more than one ammonite faunal province. The well-marked period of erosion of Middle Albian sediments in the Anglo-Paris basin which occurred during the crvistatum Subzone, is just as well marked in the Malagasy Republic (Besairie & Collignon 1956). Although not specifically stated by Young (1966) there are signs of a similar break in Texas. It is also possible that there is a break in the sequence in Peru (Benavides-Caceras 1956). In an entirely different faunal province still, the occurrence of Gastroplites cantianus in Bed VIII at Folkestone and in the lower part of the Gastroplites Zone in Canada is extremely important (e.g. Jeletsky 1964 ; Table 1, 1968). In Canada there is a definite break in the ammonite sequence although apparently not in the sedimentary sequence (Jeletsky 7m litt.), for the mcconnela Zone which contains genera such as Arcthoplites, Cymahoplites and Cleoniceras, both known from the mammuillatum Zone of the old world (Casey 1961c ; 167) is definitely of Lower Albian age. A similar ammonite faunal gap involving the whole of the Middle Albian appears to exist in Alaska (Imlay 1960 : 1961) and California. Imlay’s Cleoniceras (Grycia) presents no difficulty here because it does not possess umbilical bullae and almost certainly belongs to Beudanticeratinae. In effect, by taking the base of the Upper Albian to coincide with the base of the cvistatuwm Subzone and its provincial equivalents, it is possible to arrive at a common point of division between the two substages capable of recognition in the local successions of each country. (iv) THE ZONAL GROUPING (Table 1, p. 10) (a) The Zone of Hoplites (H.) dentatus As defined here this Zone comprises the Subzones of H. (I.) eodentatus, L. lyelli and H. (H.) spathi. This represents virtually the total range of the closely related morphological group of Hoplites represented by the index species H. (H.) dentatus. In the eodentatus Subzone, this species is not typically developed, but in fact H. (J.) eodentatus is a direct transition between the earlier Psewdosonneratia and H. (H.) of the dentatus group. This group dies out at the top of the spathi Subzone, although Hoplites (H.) continues onwards into the loricatus Zone above. With some modifi- cation, this is almost a return to the old concept of the interruptus Zone in Barrois’ and Jukes-Browne’s sense. The Zone is geographically widespread represented in sediments both condensed and uncondensed. The hoplitinid faunal province by the spathi Subzone can be shown to have extended from the western border of asiatic Russia, south to the northern margin of Tethys now represented in the Caucasus mountains. The boundary then runs along the northern side of Tethys westwards to France. The land area flanking the east side of the Atlantic rift system which existed at this time (cf. Carey 1958) apparently formed the western boundary, although the situation IN THE ANGLO-PARIS BASIN 129 in Greenland is not yet clear. Ina similar manner the primitive Arctic Ocean may have formed the northern boundary, for Hoplites is not yet known from Canada, Alaska or Japan. The province, therefore, consists of the shelf seas of Europe. In the lyelli Subzone especially, there are important links with adjoining ammonite faunal provinces in which Hoplites (H.) is as yet unknown. These links are discussed in greater detail below. (b) The Zone of Euhoplites loricatus This Zone comprises the Subzones of A. intermedius, D. niobe, M. subdelaruei and E. meandrinus. It is almost the total range of E. lovicatus which is typical of the group of Ewhoplites with sulcate rather than channelled venters seen late in the Jautus Zone. Deposits of this Zone, with the exception of the basal part of the intermedius Subzone, are of very limited occurrence in the European province. This is probably due to erosion in the early part of the Upper Albian which apparently produced a fairly general hiatus involving the lovicatus and lautus Zones throughout much of Europe except in the deeper basins. It could be argued that there is no point in dividing Jukes-Browne’s original /autws Zone into two parts, but the morphological change in Ewhoplites is quite striking at the level at which the writer has drawn the base of the Jautus Zone. Although the change in the remainder of the ammonite fauna is not quite so clear cut, nonetheless it does occur at about the same point in time. The ammonite fauna of the lovicatus Zone is grosso modo sufficiently distinct for it to be capable of definite recognition at zonal rank. Spath placed the division between the dentatus and Jautus Zones in his sense at the top of the niobe Subzone where in fact there is no significant change in the ammonite fauna. This quite arbitrary and meaningless arrangement is firmly rejected here. The intermedius Subzone has as great a geographical range as the spatht Subzone of the dentatus Zone but known sediments of the niobe, subdelaruet and meandrinus Subzones are preserved in only a very limited area, that of eastern England and northern France. Links with other ammonite faunal provinces are very few and mainly with the tethyan belt. (c) The Zone of Euhoplites lautus The Jautus Zone as now defined consists of two Subzones ; that of Euhoplites nitidus and that of Anahoplites daviesi. It is essentially the total range of Euhoplites lautus, and the contemporary species of this genus with their well-marked clean cut ventral channel. The base of the Zone as indicated above is defined by the quite sudden change in the peripheral aspect of Ewhoplites. The top is defined by the appearance of Dipoloceras bouchardianum and Beudanticeras beudanti indicating the base of the cristatum Subzone. Deposits of the nitidus Subzone are of very limited known geographical extent. They are known from eastern England and northern France, and apparently occur also in Poland, but these are probably only remnants which survived the basal Upper Albian erosional movements. The daviest Subzone can definitely be identified in Russia (Mangyshlak Peninsula) but this is the only area outside the eastern Weald of England that deposits of this Subzone have as yet been recognised. Russian I 130 MIDDLE ALBIAN STRATIGRAPHY workers (e.g. Glasunova 1953a ; 18) have recognised above the dentatus Zone, which in effect is equivalent only to the spatht Subzone, a Subzone of Anahoplites asiaticus. It is apparent that this is, in part, of entermedius (e.g. Kopet Dagh, Mangyshlak), and in part of daviest Subzone age (e.g. Mangyshlak). Anahoplites asiaticus and A. tvanscaspius Glasunova (1953a) look like early intermedius Subzone Anahoplites com- parable to, although perhaps not specifically identical with species known in the uppermost spathi and basal intermedius Subzones of England and France. A some- what different scheme has been proposed by Sokolov (1966) and this is discussed below (p. 132). V. LINKS WITH OTHER FAUNAL PROVINCES The following is a brief review of the known links between the hoplitinid and other faunal provinces at certain levels in the Middle Albian. A vast amount of work still remains to be done to determine the degree of representation of Middle Albian sediments throughout the whole surface of the Earth and so to determine accurately the boundaries of the various faunal provinces. It is becoming apparent, however, that sediments of Middle Albian age are far more restricted in occurrence than those of the Upper Albian, and in many areas where they both occur, there is often evidence of a hiatus between them. Basal Upper Albian sedimentation in widely scattered places on the Earth commenced after a period of erosion (e.g. Europe, and the Malagasy Republic), or they transgress onto very much older surfaces (e.g. Africa). The fauna itself shows evidence of unstable conditions at the base of the Upper Albian (p.127). Whether Middle Albian sediments were deposited over a widespread area of the Earth only to be removed largely by subsequent erosion is a matter of conjecture. Here, however, we are concerned only with an outline sketch of the boundaries of our province and at what definite levels it is possible to correlate with adjoining provinces. A. The boundaries of the hoplitinid province (text-fig. 50) The westward boundary of the hoplitinid province during the Middle Albian was formed by the massifs of Morvan and Armorica. These separate the European shelf- sea from the narrow sea-way connected with the Tethyan belt which was then the ‘Atlantic’ (Carey 1958 ; Bullard et al., 1965). No species of Hoplites, Euhoplites, Anahoplites or Dimorphoplites have yet been found in the United States of America and Canada. However, there are tantalising references to a typical hoplitinid fauna in argillaceous sediments in the coastal area N. of Scoresby Sound, E. Greenland (Spath 1946 : Donovan 1949, 1953) which demonstrate that this area also is to be included in the province. If E. Greenland is brought back to its apparent middle Cretaceous position, the coast N. of Scoresby Sound is approximately opposite the northern outlet of the present day North Sea basin. At the present time no information is available about Middle Albian sediments in the North Sea Basin, but the evidence from the eastern margin of England and from deep borings in Holland suggest that sediments of Middle Albian age thicken towards at least the south central part of the Basin. The Middle Albian sediments of Ger- PARIS BASIN LO IN THE ANG SUOTJIIUTLOD FO Sole OY LL “suOT}IosUT po}zOp Aq poyzeorpur st courAoId ueAY ZT oy} YIM ‘gut] poyood Aq poezeorput souraAoid jeunes optuoWUIe prurytdoy uerqyy e[ppr ey} Jo Arepunog ozewTxo1ddy 0S “DIT 132 MIDDLE ALBIAN STRATIGRAPHY many belong to the hoplitinid province and these extend through Poland (e.g. Cieslinski 1959) into Russia, although they are largely concealed by later rocks. In this respect it is interesting to note that Ravn (1925) has figured ammonites from the Cenomanian basal conglomerate on the Baltic Island of Bornholm. These indi- cate not only that elements derived from the tardefurcata and mammillatum Zones are present en melée with Cenomanian ammonites but also his Sonneratia Baylei (pl. III, fig. 6a, b) looks like an Anahoplites suggesting the possibility of Middle Albian material also being represented in the deposit. This paper seems to have escaped the attention of previous English workers (see also @dum 1928 ; 44-5), and throws light on the provenance of the glacial erratics described by Skeat & Madsen (1808) from the Jutland drift. The hoplitinid province in the Middle Albian may not include all of Russia in Europe, but it certainly extends as far east as the southern Urals and the eastern border of the Caspian Sea south to the Kopet Dagh in the border region with Iran. The area of Daghestan flanking the western side of the Caspian, and the area between the Mangyschlak Peninsula and the Kopet Dagh is of considerable interest. From the ammonites figured by Semenov (1899), Sinzov (1909 : I9I5) and Glazunova (1953a, b) together with the recent stratigraphical work carried out by Sokolov (1966) it is apparent that Middle Albian sediments are well developed in this area. Sedi- ments of lyelli Subzone age appear to be absent, but there is a good fauna of Hoplites (H.) spp. indicating the spathi Subzone (the dentatus Zone of Sokolov). The inter- medius Subzone is also definitely represented including the basal part with Ana- hoplites of evolutus type. The next horizon which can definitely be correlated with the sequence in the Anglo-Paris basin are Sokolov’s zones of ‘ Anahoplites ’ rossicus (Sinzov) and ‘ A.’ whligi (Semenov). These forms can be matched in the cristatum Subzone of Kent, and are descended directly from Anahoplites of the daviesi group, which together with its ‘variety’ orvnata, are also known from this region of the U.S.S.R. Spath (1943 ; 732) was quite incorrect in comparing ‘ A.’ uhligi with A. daviest ; the two are quite distinct although closely related. Between the Zone of ‘ Anahoplites’ rossicus and that of A. intermedius Sokolov recognises in ascending order a Zone of Daghestanites daghestanensis Glasunova and a Zone of Anahoplites kelendensts sp. nov. (of Sokolov which appears to be undescribed). Daghestamtes daghestanensis Glasunova has not yet been recognised outside the Soviet Union, and Anahoplites kelendensis in the absence of figures cannot be com- pared. Undoubtedly the most striking feature of the Middle Albian sequence in this area is the apparent total absence of Euhoplites so prolific in the area of Western Europe and present also in Greenland. In Siberia the Albian is represented in a continental facies. The spatht and intermedius Subzones are certainly represented on the northern margin of the tethyan belt in northern Bulgaria (Zakharieva-Kovatcheva 1957, Nikolov 1965, 1970). Seitz (1930) has figured a definite spathi Subzone fauna on the same margin in the Rhaetic Alps at Vorarlberg, Austria. From there westward the southern boundary of the province follows the margin through Switzerland and into France. The Albian ammonite fauna of the tethyan belt is quite distinct in char- acter from that of the European shelf seas and the hoplitinids are absent from Albian IN THE ANGLO-PARIS BASIN 133 sequences south of it. The alleged occurrence of Hoplites (H.) in Mexico has not yet been substantiated by illustrations. B. Links with the sequences of other countries There are two rather fortuitous major links between the hoplitinid faunal province and other faunal provinces. The first of these comes in the lyelli Subzone near the base of the Middle Albian, the other in the cvistatum Subzone at the base of the Upper Albian. Between the two there are very few links known. (i) WEST PAKISTAN Spath (1930b) described an Albian fauna from the area of Hazara, now Abbotabad, in W. Pakistan. The ammonites come from a condensed deposit which yielded possibly mammullatum Zone, and definitely lyelli Subzone fossils. The lyelli Subzone is indicated by the occurrence of Lyelliceras lyelli, L. cotteri, species of Oxytropidoceras (sensu lato) and Brancoceras. However, no species of Hoplites (H.) have been re- corded. No direct comparison can yet be made with the sequence in the U.S.S.R. where this Subzone has not yet been detected, and in fact in the hoplitinid province the Subzone is not represented E. of the western area of Switzerland. No other Middle Albian links are known from Pakistan, although the cristatum Subzone is definitely represented. The two specimens of Oxytropidoceras figured by Spath (1934b ; 18-21, 30, pl. vi, figs. 1, 2) from the Attock district are of Middle Albian age, but cannot be assigned to a subzone at this time. (ii) TETHYAN BELT As yet very little knowledge exists on the degree of Zonal and Subzonal repre- sentation in the Middle Albian sediments of the part of the tethyan belt stretching westwards from W. Pakistan through Iran and Asia Minor, the Mediterranean countries to reach the proto-Atlantic on the W. coast of Spain. It is clear that the phylloceratids, some lytoceratids, and desmoceratids, where they occur, are too long time-ranging to be of even zonal value. Desmoceras latidorsatum, for example, occurs in the mammullatum Zone, as well as in the lyelli and intermedius Subzones in the Middle Albian hoplitinid province. From the discussion of the American sequences it seems that Oxytropidoceras sensu lato may also include long time-ranging species. However, the mojsisovicsiinids, and in particular the engonoceratids may eventually aid correlation with the provinces to the north and south of Tethys. In this respect the distribution of Platiknemiceras is of significance (Casey 1961b). The strati- graphic range of this genus as indicated by Casey can in two instances be narrowed. It is associated with an example of Lyelliceras gevreyi at Hamiran, Iran (BMNH., C 68410) cited by Spath (1931 ; 315) and recorded as Prolyelliceras by Casey (1961b ; 354). This specimen shows the extra-intercalated siphonal crenules and tendency to en-echelon ventro-lateral crenules characteristic of forms which occur at the base of the lyelli Subzone. L. flandrini crenulata discussed below is of the same age and is also associated with Platyknemiceras. 134 MIDDLE ALBIAN STRATIGRAPHY (iii) ALGERIA Although it is in need of revision, the work of Dubourdieu (1953 : 1956 ; 185-228) indicates that at least the equivalent of the lower part of the /yelli Subzone is well represented by sediments in the Monts du Mellégue, Djebel Ouenza, Djebel Def, the environs of the Djebel Hameima, and the Djebel Bou Khadra. The ammonites include Lyelliceras flandrini Dubourdieu and L. radenaci (Pervinquiére). L.flandrini has extra-intercalated siphonal crenules indicating the lower part of the /yelli Subzone, and this is confirmed by L. flandrini crenulata (1953 ; pl. III, figs. 25-35) which is closely comparable to the inner whorls of the grade reached by L. gevrey (Jacob) in Bed 1 at Courcelles (Aube). JL. vadenaci occurs also in the lyell1 Subzone of the Guilford Colliery, Kent (p. 76). (iv) SOMALIA Tavani (1949) has described and figured what appears to be a lyelliceratid under the name Somalites vertebralis. This is associated with Brancoceras and they may well indicate the equivalent of the /yelli Subzone. However, Somalites has not been found outside its type locality. (v) MADAGASCAR Collignon has demonstrated recently that the lyelli Subzone is represented without question in the Middle Albian sediments of the Malagasy Republic (1963, 1965a) and he employs the term Zone a Lyelliceras lyelli. Lvyelliceras lyelli and close relatives were found by him at Khomihevitra (1963 ; pl. 315, figs. 1333-5). It should also be noted that the fauna of brancoceratids described by him (1949) from d’Ambara- maninga could well indicate a basal Middle Albian age for the sediments which con- tain them. The species of Pseudosonneratia from the same bed certainly do not belong to that genus. Dzpoloceras cristatum, and contemporary species of this genus, marking the unconformable base of the Upper Albian sediments, occur at Andrano- fotsy (e.g. Collignon 1963 ; 2). At present it is not possible to correlate the inter- vening Middle Albian sediments, referred to a Zone a Oxytropidoceras acutocarinatum and Manuaniceras jacobt in the Malagasy Republic, with those of Europe or America. (vi) SOUTH AMERICA Ammonites of Middle Albian age have been well illustrated from Colombia and in particular Peru, and for the purpose of the present comparison these only will be considered. Important Middle Albian faunas are also known from other South American countries such as Venezuela and Brazil but these have not yet been figured in full. (a) Colombia In Colombia, Gerhardt (1897 ; 168-170, pl. IV, figs. 8a, b) described an ammonite which he named Acanthoceras prorsocurvatum from Ubaque (Cundinamarca) and IN THE ANGLO-PARIS BASIN 135 considered it to be of Aptian age. Douvillé (1906) recognised it to be of Albian age and figured a fragment (1906 ; pl. II, figs. 1, 1a) which Spath (1930b ; 65 footnote) later renamed Prolyelliceras peruvianum, the type species of his ‘genus’. Riedel (1934 ; pl. 9, figs. 9-11) figured another specimen as Prolyelliceras? lobatum confirm- ing a Middle Albian age for these forms, because they are associated with Lyelliceras of the lyelli type also figured by him. From specimens in the British Museum (Nat. Hist.) e.g. BMNH C 74786 J. V. Harrison Colln., from the road between Viola and Portillo, it is apparent that these so-called ‘ Prolyelliceras ’ are in fact large specimens of Lyelliceras of lyelli-ulrichi type, the ornament of which modifies at diameters which are as yet unknown in the old world. Pvolyelliceras is considered here to be a junior subjective synonym of Lyelliceras, and the lyelli Subzone is apparently well repre- sented in Colombia. (b) Peru In the last twenty years our knowledge of the Middle Albian zonal stratigraphy of Peru has been greatly increased by the work of Knetchel (in Knetchel et al., 1947) and Benavides Caceras (1956). It is apparent that the lyelli Subzone is well repre- sented in the Pariatambo, Crisnejas and Chulec formations classified by Benavides Caceras with the Zone of Oxytropidoceras carbonarium. These sediments, between 100 and 200 metres thick, have yielded ammonites such as Desmoceras latidorsatum, Lyelliceras lyell, L. ulricht and Eubrancoceras aegoceratoides, all known from localities in the Anglo-Paris basin, especially at Courcelles (Aube). It is interesting to see that Benavides-Caceras records Lyelliceras pseudolyeli from Bed 20 of the Crisnejas locality classified by him with the underlying Knemiceras raimondii Zone. It is also instructive to compare the sequence of Zones recognised in Peru with that of Algeria. As yet Mojstsovicsia has not been found in the lyelli Subzone in the Anglo-Paris Basin but it does occur in the overlying spathi Subzone where it is represented by M. delaruei and subspecies. The genus is represented in Peru by the type species of Mojstsovicsia, M. ventallinensis (Gabb) whose exact Subzonal age is uncertain (Douglas 1921). It is also uncertain at present whether there are any higher Middle Albian sediments than those of the lyelli Subzone preserved in Peru, but it appears that the Subzonal sequence is incomplete reflecting the break in sedimentation seen elsewhere in the World. (vii) TEXAS Young (1966) has presented an extremely important work on the ammonite zonation of the Fredericksburg Division of the Texas Albian and on the mojsisovic- siinid ammonites contained in it. He presents a correlation of the Texas zonal sequence with that of Europe. Following a discussion of the faunal sequence both in Texas and elsewhere outside the United States, he examines four possible con- clusions raised because of an apparent anomaly which exists between the carbon- avium Zone of Peru and that of Texas. In Peru the carbonariwm Zone of Benavides Caceras contains Lyelliceras and it is here correlated with the lyelli Subzone of the 136 MIDDLE ALBIAN STRATIGRAPHY European Subzonal sequence. In Texas, Young’s carbonarium Zone does not con- tain Lyelliceras and the possible conclusions that he poses are as follows (1966 ; 18). ‘ 1. We do not understand yet the taxonomy and ranges of species of Lyelliceras. After all, the entire family Lyelliceratidae is still little known. 2. The rocks between the dentatus and mitidus subzones are greatly con- densed in Peru, Venezuela, and Colombia. 3. The beds in Texas without diagnostic ammonites (Upper Glen Rose and lower Walnut Formations) are to be correlated with the dentatus and benettianus subzones, and the zones of salasi and carbonarium are condensed and represent all of the Folkestone section between the dentatus and cristatum subzones (= beds II-VII, inclusive). ‘‘ 0.” carbonarium 1s interpreted with such latitude that it could include forms of the salasi zone of Texas. 4. The ammonite zones are migrating against each other. In other words, Lyelliceras is younger in South America than in Europe, and Manuaniceras carbonarium is younger in Texas than in South America. This possibility will be distasteful to orthochronologists, but it is a factor that cannot be overlooked and is supported by the occurrence of Inoceramus concentricus with Lyelliceras (Benavides, 1956, p. 414). I am inclined to look with favor on the first explanation, but it is a personal preference. In the final analyses, some combination of two or more of these explanations may seem preferable. I must point out, however, that Benavides’ (1956) section descriptions do not indicate condensation.’ Unfortunately it is necessary to point out that the evidence for his correlation of the Texas Middle Albian zonal sequence with that of the Anglo-Paris basin is non- existent. The only direct correlation that can be made between the two areas is in the cristatum Subzone. Dzipoloceras fredericksburgense and D. cristatum are known from the upper part of the Goodland Limestone in Tarrant Co. Texas. Inoceramus subsulcatus was figured by Bose (1927; 189-193, pl. XVIII, figs. 1-5) from the Edwards Limestone which is of the same age. But perhaps the most significant link is provided by Oxytropidoceras cantianum Spath (1931 ; 350-1, pl. 32, fig. 5) which is almost identical to the specimen of ‘ Manuaniceras carbonarium transitional to M. peruvianum multifidum (Steinmann) ’, figured by Young (1966 ; pl. 17, fig. 6) and which is also from the upper part of the Goodland Limestone (= cristatwm Sub- zone). The only other possible link is provided by Difoloceras of the cornutum group also known from the Goodland Limestone (e.g. Spath 1931 ; 363 text-fig. 118). Now we have the measure of the problem. Oxytvopidoceras in the wide sense occurs in the Anglo-Paris basin in the mammullatum Zone (Lower Albian), in the lyelli and spathi Subzones (Middle Albian), and in the cvistatwm Subzone (Upper Albian) ; it is, therefore, a very long-ranging group. The development of the genus Lyelliceras is now well known both in the hoplitinid province and outside it, and the evidence indicates that the beds containing it in Pakistan, Madagascar, Algeria, Colombia, and Peru are of the same age as those containing Lyelliceras in the Anglo-Paris basin. Therefore, the specimens of ‘ Oxytropidoceras’ carbonarium from the lyell1 Subzone sediments of the Pariatambo Formation of Peru cannot be of the same age as those 1 It is now known from the Loricatus Zone of north Kent (Owen in press). ——— IN THE ANGLO-PARIS BASIN S77 occurring in the Goodland Limestone of Texas where they are associated with Dipoloceras of the cristatwm Subzone. It now becomes apparent that certain species of the group typified by Oxytropidoceras, like other tethyan genera, may be very long time-ranged. Unlike the hoplitinids which show a great deal of morphological differentiation, Oxytropidoceras and its closely allied genera show comparatively little such differentiation. On their own, it might prove very difficult, except in a few cases, to use them for the fine subdivision of which the hoplitinids have in particular proved capable. As yet no attempt has been made to compare the species of Oxytropidoceras (s.lat.) which are known from the lyelli and spatht Subzones of the Anglo-Paris basin with those occurring outside the hoplitinid province. It might well prove possible eventually to correlate the spatht Subzone with the tethyan succession (including Texas) on the basis of certain species of Oxytropidoceras (s.lat.). At the moment the intermedius and mobe Subzones have no exact zonal links with Tethys although long ranged tethyan forms are known from both time spans. Mojsisovicsia in the sub- delavuet Subzone should be a renewed tethyan incursion, but none of the species from this Subzone or the lautus Zone have yet been recognised elsewhere. So, at this time it is not possible to correlate the Zones recognised in Texas with those of the Anglo- Paris basin. It is however, apparent from Texas and Madagascar that sediments characterised by the group typified by Oxytropidoceras occur between the /yelli and cristatum Subzones. Although sedimentary breaks can be difficult to detect in carbonate-marl sequences it seems to the writer that Young’s salasi and carbonarium Zones are high Middle Albian as he states. (vii) CANADA The zonal scheme of the Canadian Albian has recently been ably reviewed by Jeletzky (1968), but although this represents a refinement on his earlier review of 1964 it is still open to criticism. In 1964 Jeletzky indicated that the Zone of Arcthoplites mcconnelli contained Cleoniceras and Cymahoplites. If these ammonites are correctly assigned generically then together they indicate a Lower Albian, mam- millatum Zone age in the sense of Casey (1961a ; Table 1) and herein. Cymahoplites occurs in the mammillatum Zone of Europe (Casey 1961c ; 165-169, Pl. XXIX, figs. ta-d), and although Cleoniceras (C.) ranges from the tardefurcata Zone (regularis Subzone) to the basal Middle Albian eodentatus Subzone, the weight of evidence, from the associated ammonites indicates a mammillatum Zone age. There is no evidence at this time to indicate that the Subzones of Lemuroceras irenense and L. mcconnelli are the correlatives of the European Subzone of Douvilleiceras inaequinodum (Jeletzky 1968 ; Fig. 1) now the basal Middle Albian Subzone of Hoplites (Isohoplites) eodentatus. The Gastroplites Zone has been equated by Jeletzky (1968 ; Fig. 1) with both the daviesit Subzone (Middle Albian) and the cristatum Subzone (Upper Albian). How- ever, G. cantianus Spath which occurs in the Gastroplites Zone in Canada occurs also in Bed VIII at Folkestone its type locality. It is undoubtedly of cristatwm Subzone age, and there is no evidence for correlating the daviest Subzone with any part of the Gastroplites Zone at this time. 138 MIDDLE ALBIAN STRATIGRAPHY Between the Gastroplites Zone marking the base of the Upper Albian and the meconnelli Subzone is a thick interval of shales which have not yet yielded ammonites. Jeletzky has classified these sediments with a Zone F which he considers to include part or all of the time span between the mammillatum ‘Subzone’ and the cristatum Subzone (1968 ; 17-18, Fig. 1). If there are any Middle Albian sediments in Canada then they are contained in these shales of Zone F. At the moment, however, no Middle Albian ammonites are known from Canada. It is worth noting that the alleged Cleoniceras associated with a gastroplitinid ammonite fauna in Alaska (Imlay 1961) does not stand up after examination. Cleoniceras (Grycia) sablei Imlay which is known from crushed material does not appear to possess umbilical bullae and is here considered to be a member of Beudanticeratinae. The gastroplitinid Upper Albian province included the area that is now the western cordillera of North America stretching from Alaska to California. (ix) GREENLAND Our knowledge of the Albian sediments of the area between Traill O. and the Wollaston Foreland on the E. coast of Greenland N. of Scoresby Sound, is due to the work of Spath (e.g. 1946 ; 8-10) and Donovan (1949 ; 6-7 : 1953, 35-37, 50-51). It is tantalising in its incompleteness for it seems that in this area we have the boundary between the European Albian province and that of the area of Canada and the western cordillera of N. America. Both Spath and Donovan record Lower Albian ammonites which occur in both provinces ; Middle Albian ammonites such as Hoplites and Euhoplites which are characteristic of the European hoplitinid province ; and Upper Albian ammonites which may also link the two provinces. (x) CONCLUSION The foregoing very brief review indicates that a considerable amount of work now requires to be done on Middle Albian sequences outside the Anglo-Paris Basin along the lines attempted here. The object of this review is to stimulate such research. Superficially, it seems that there is in many parts of the Earth a major break in sedimentation, particularly at the top of the Middle Albian. General sedimentation occurred once again in early Upper Albian times. There is evidence of this even in the area of Kent and Sussex, wherein the Jovicatus and lautus Zones are apparently the most completely represented by sediments. Breaks of such an extensive nature in the Cretaceous, must be due to major events in the Earth’s crustal development, for there is no evidence of unusual climatic conditions of sufficient magnitude to reduce sea-level by a significant amount. There has always been a tendency to equate movements on a regional scale in Europe with various periods of deformation in the Tethyan belt. Until recently the development of the Atlantic, Arctic and Pacific ocean basins has been largely ignored and yet with recent geophysical work we are now beginning to see the important effect that initial faulting must have had even on Cretaceous sedimentation. The ————————— IN THE ANGLO-PARIS BASIN 139 Royal Society’s Symposium on Continental Drift posed many new questions for the stratigrapher and challenged many long held concepts. The important reviews by Wilson (1965 ; 228-251), and Maack (1969) on the formation of the ocean basins drew particular attention to the role and effect of initial major rift, block and transcurrent faulting in the Jurassic and Cretaceous before the pulling apart of the old continents to the positions of the new within the Tertiary. The evidence of faulting and igneous activity indicate that the pulling apart of the continental masses bordering the present day Atlantic commenced earlier in the southern Atlantic (e.g. Maack 1969). In the northern Atlantic the vulcanism commenced in the Tertiary. The major faulting must at times have had a profound effect on the distribution and depth of water, and thus the depositional and erosional conditions, in the continental shelf seas. This would produce characteristics quite distinct from the pressure of the African continent against Europe which in the Tertiary culminated in the Alpine ‘storm’. During the Albian there is good evidence of the effect of this faulting, associated with the separation of Africa and South America, in and around Africa (e.g. Furon 1963). Even in southern England faulting occurred during cristatum Subzone times associated with marked erosion of Middle Albian sediments. This is but one symptom of one short period of crustal instability which is apparent in both the sediments and fauna in a number of areas in the World and points to a significant event in the development of the Earth. The old idea of a Jurassic and Cretaceous North Atlantis continent now foundered below the N. Atlantic was not so far off the mark. However, this ancient land mass was the continental area which is now Greenland and Canada, long before it was broken up and pulled away from Europe since the Tertiary to the present day. It is apparent that the boundary between the Albian ammonite provinces of the deposi- tional areas that is now Europe, and that of Canada and the Western Cordillera of N. America, occurred in the sea-way represented by the sediments in E. Greenland. VI. CONDITIONS OF DEPOSITION IN ENGLAND From the stratigraphical account of the Middle Albian sediments given above it is possible to obtain some idea of the conditions which influenced their deposition in England. Before commencing the discussion of these it is essential to consider first two factors which provide a key to the interpretation of the field evidence. It is apparent that the early Upper Albian (cristatum and orbignyi Subzones) tectonic movements caused the planing-off of the upper surface of the Middle Albian sediments throughout England. This period of erosion, although not as great as Kitchin & Pringle held (1922a), removed a considerable amount of sediment, including marginal deposits. Within a reasonably narrow limit the resulting surface was probably plane, and for the purpose of this study it is taken so to be. From this datum level, by comparing both the surviving thickness and the lithological sequence from place to place, it is possible to make out the configuration of the surface upon which the Middle Albian sediments were deposited. It appears that there were only comparatively minor regional tectonic movements within Middle Albian times. These seem to have consisted of minor shifting of the axes of older folds indicated below, causing condensation or increased sedimentation. 140 MIDDLE ALBIAN STRATIGRAPHY The main factor governing sedimentation appears to have been the pattern of parallel ridges and troughs produced initially in late tardefurcata Zone times by a comparatively mild folding phase. Casey from the field evidence afforded by largely vemamé mammullatum Zone deposits interpreted these troughs as ‘ dimples ’ (196ra), but the Middle Albian sediments have provided far more definite information on the trend of these structures (text-fig. 52). Although the ridges were not obviously active structures the sediments thin across them due to water-current activity, and probably to some gravitational movement of clay particles down-slope. During minor periods of current erosion the degree of condensation is greater in the area of the ridges as one would expect. (a) The Margins of the depositional basin in England and Northern France (text-fig. 51) To what extent the Brabant massif and the London Platform acted as positive areas in Middle Albian times is far from certain. Nothing is yet known of the Gault sequence in the area of the North Sea adjacent to the shores of Kent, Essex, Suffolk and Norfolk. There certainly is no evidence made available at this time of the land area suggested in this region by Jukes-Browne’s frontispiece map (1900). It is also apparent from the borings in the Cliffe area of Kent (Owen in press), that renewed movements along late Jurassic or early Cretaceous faults in the area of what is now the Thames estuary, caused strong current action which removed Middle Albian sediments over the southern part of Essex. This disturbance contributed to, and was associated with other movements which planed-off the upper surface of the Lower Gault throughout the Anglo-Paris Basin. How much sediment and the areal extent that has been removed is at present unknown, but in Kent, and in Cambridgeshire and Norfolk, where Middle Albian sediments are preserved, there is no evidence in the sequence of an area of Palaeozoic rocks actively undergoing erosion to the east. A shoal area existed in north-west Norfolk and in the area of the Lincolnshire and Yorkshire Wolds and to an unknown extent in the adjacent area of the North Sea. Its position is indicated by the pebbly development of Bed C of the Hunstanton Red Rock (Wiltshire 1869 ; 185-188) of Middle Albian age, and its lateral equivalents in the Red Chalk with its shallow-water fauna. To the south and east in Norfolk, Bed C is replaced by clays of the contiguous Lower Gault. This shoal area probably flanked the Palaeozoic massif of the Pennines and its southerly extension of the Peak District and a possible positive area in the adjacent North Sea (Collette 1968 ; 20). Gault clay probably existed south of the Pennine massif because derived Albian fossils are known from the glacial boulder clay as far north as Chellaston, Derbyshire, as well as elsewhere in the Midlands. On the balance of evidence the writer is inclined to doubt that the Middle Albian sea extended into the Cheshire lowlands but this could prove to be incorrect. The clays of the lyelli and spathi Subzones at Swindon (Badbury Wick) and at Devizes are very silty. Those of the intermedius Subzone at Devizes and Didcot are even coarser in grade. These examples do not necessarily indicate the proximity of a marginal area but equally they do not suggest an extensive basin area to the north west. NORTH SEA BASIN > ARDENNES mS xX NY \ | | oe | 3 xX MORVANO-VOSGES \ STRAIT MORVAN / yi Fic. 51. Palaeogeographic map of the Anglo-Paris Basin in the Middle Albian showing links with the North Sea Basin, and Tethys via the Morvano-Vosges Strait. The Aquitaine Basin is linked with Tethys via the proto-Atlantic. 142 MIDDLE ALBIAN STRATIGRAPHY Nonetheless, the outcrop from Aylesbury (Bucks.) to Okeford Fitzpaine (Dorset) shows a section across a basin in which the /yelli Subzone in particular is well devel- oped, and apparently the zmtermedius Subzone as well. Whether the margin of the Middle Albian depositional area ever reached Palaeozoic rocks in the Welsh borders is unknown. However, it seems more probable that the margin flanked a land area of Jurassic rocks from the nature of the sediments of the Gault in this area (compare the relationship seen in the Ardennes). There is no doubt that a con- siderable volume of clay sediment was carried eastwards into the depositional area throughout Middle Albian times (p. 147) (cf. Jones 1955). It has been shown (p. 53) that as one proceeds westwards along the south coast from the Isle of Wight to the Devon border the basal fossiliferous bed and presumably the underlying pebble beds become later in age. In the deeper part of the Wessex Basin in the Isle of Wight, fine grade lyelli Subzone sediments rest upon coarsely- graded marginal mammullatum Zone Carstone. By Lyme Regis, the lowest fossili- ferous sediments are of intermedius Subzone age consisting of very gritty clays, and rest upon a pebble bed which is of uncertain Subzonal age but probably not older than spathi. The evidence indicates marked diachronism of the base of the Middle Albian sediments, and the progressive transgression of the sea westwards across Jurassic sediments particularly during the spathti Subzone. The furthest margin in the extreme west probably followed the eastern boundary of the Mendip Hills and across to the area of what is now the Blackdown Hills. There is no evidence of any Middle Albian sediments in the western half of the English Channel. On the northern coast of France, Middle Albian marginal sediments probably flanked the Palaeozoic rocks north of the Cotentin Peninsula. They are certainly present in the Pays de Caux where sediments of the eodentatus and niobe Subzones consist of very coarse pebbly loams with a high clay content. However, the available evidence from the outcrop and boreholes indicates that the land margin was not to the south-west, south, or south-east, and it is necessary to look for a ridge which underwent active erosion during the Middle Albian in the Baie de la Seine. There seems no doubt that the western margin of the Middle Albian Paris Basin was flanked by Jurassic sediments fringing the Armoricain Massif (text-fig. 33). In the Artois, the eastern margin of the Middle Albian sea was formed by the Brabant Massif. In the Boulonnais at Caffiers, and in borings in the area of the Franco-Belgian border, Albian sediments rest upon Palaeozoic rocks on the fringe of the Massif. Of particular interest here, especially in connection with the thinning of Middle Albian sediments in the extreme east of Kent, is the marked rise in the Palaeozoic floor in the region of the Quenoc off-shore from Cap Blanc Nez (p. 83). In general, therefore, it is apparent that in England and in France a progressive transgression over earlier Cretaceous and on to wide areas of Jurassic sediments occurred between the eodentatus and niobe Subzones. Whether this continued later into the loricatus and lautus Zones is uncertain because early Upper Albian erosion has removed the evidence. From this definition of the margin of the northern part of the Anglo-Paris Basin, it is now possible to look at the structures within the de- positional area in England. IN THE ANGLO-PARIS BASIN 143 (b) The Structural Controls on Deposition in southern England (text-fig. 52) The Variscan Wessex Basin of Kent (1949 ; 99) and its continuations into the Weald and across the Channel into France subsided fairly steadily throughout the Jurassic roughly in pace with the sediments which infilled it. At the end of the Jurassic and at the opening of the Cretaceous Period, a strong phase of folding and faulting occurred which in Dorset must have included fold amplitudes of well over 1000 feet (>305 m.). The resulting basin of sedimentation was very greatly reduced in area in comparison with that of the Jurassic. The history of Lower Cretaceous sedimentation in southern England is the progressive erosion of the resulting land area of Jurassic sediments and their redeposition within the basin. This basin was by now restricted to the area of the Weald proper and eastern Hamp- shire, and the English Channel flanking the Isle of Wight and Sussex. That the deformation was essentially early Cretaceous is indicated by the distribution and character of the Purbeck Beds and contiguous deposits. The marine Cinder Bed within the Purbeck Beds of Dorset and equivalent horizons elsewhere are considered by Casey to mark a marine incursion from the direction of the North Sea Basin (1963). The sea did not invade southern England again until the early Aptian. It is also important to note that in the Speeton area it is the top of the Kimmeridge Clay which is eroded and that heavy clay sedimentation did not commence again until after the start of the Neocomian. The depositional history of the Lower Greensand has been discussed by Casey (1961a ; 499-501). At the end of the tardefurcata Zone (Lower Albian) there occurred the last of a number of minor folding phases which Casey has demonstrated affected sedimentation during the formation of the Lower Greensand. This last phase produced a number of parallel ridges and troughs trending between NW. and SE. to WNW.-ESE., the axes of which were slightly modified during mammullatum Zone times and again later in Joricatus Zone times. These, together with a general subsidence of the whole Basin both in England and France oy a rise in sea-level, set the stage for Middle Albian sedimentation. The positions of the axes of the structures are shown diagrammatically in text-fig. 52. The Middle Albian sequence under Dover shows a good development of the lyelli Subzone overlain by a nodule bed of lower spathi Subzone age. By Folkestone the lyella Subzone sediments are greatly reduced in thickness but the overlying dentatus nodule bed is of exactly the same age as at Dover. The rest of the Lower Gault sequence also is thinner at Folkestone, where it rests upon a mammillatum Zone sequence in which all four Subzones are represented. At Sandling Junction, the basal Gault rests upon puzostanus Subzone sediments as at Folkestone, but these in turn rest directly on an eroded surface of early tardefurcata Zone sediments. Here, the dentatus nodule bed contains species of Hoplites (H.) transitional between those of the dentatus nodule bed at Folkestone and Dover, and those which occur in the ‘ upper dentatus-spathi nodule bed’ in the northern Weald. From Sandling to Maidstone, puzosianus Subzone sediments rest upon either tarde- furcata or jacobt Zone Folkestone Beds, and the dentatus nodule bed in the basal Gault MIDDLE ALBIAN STRATIGRAPHY 144 ‘UOI}EJUIUIIPIs ULIQTY S[PPIN SUlOUeNpUr soxe [eInjonI}s 9y} SULMOYsS pue[sUY ysey YNOS Jo deur yo}eHS WDYUS2/2234M-25M WDUOIM-4IM JSIPSPUDUIM-IM UOID27 112M} S2M-2M 24M-M 2uopPSudWYIy-1y 2Bpispundy—1 u0}Bu1ss04S—-35S s2a2Assuanbs—bs Avg sz2406bsu0w 3S-EBWS ‘2S “OI 242uS-uS 2U4OQ 125-125 SYDOUDA2ZS—-as Buijpuns-0s umMOopuDS-Ss A2| HOO Y-OY pinomBuiy-y UMOPS }JO0g—Og UVJOMS2IPPDd-—d POOMAN-AN ssog Ag 2u0}spiow-gaw S420SSDH-DH 11DH YORJOH-HH AsPi1OD Psojyting-ng 2u0}S32y/04-04 Buiqqo4-—4 322435 2usOYAR-Sa 3221399q93-3 uz2uy vO.UNG-5g Avg vO}dwo5-05 2ysD-1D puojs} A2Au0D-[D Asdipiod 32IS!UD-uD pud|x2ng-ng Buv6y201g-19 ausnoqgnsg-g ys11pAy-Ay uo}buippy-y IN THE ANGLO-PARIS BASIN 145 has exactly the same degree of representation as at Sandling. There is strong evidence to indicate that in lithological sequence and Subzonal representation the remainder of the Gault sequence is uniform between Brabourne and the A 249 Clover Leaf on the Maidstone By-Pass, and they are certainly identical from Hollingbourne to the A 249. In the area of the Kent Coalfield to the east, the pattern is not so clear but the eodentatus and lyell1 Subzones sediments are well developed to the N. and NW. of Dover in the Guilford, Tilmanstone, and Chislet collieries. The Lower Gault as a whole is much thicker here than at the outcrop, but further east, on the Thanet and E. Kent coast, the Gault in its entirety thins rapidly. At the valley of the Medway north of Maidstone, the outcrop swings westwards through an arc of about 12°. The change in the lithological sequence is striking (text-fig. 3, p. 14) as the outcrop turns away from the line parallel to an axes to one that cuts across the structural trend. From the four-division sequence in the Maid- stone By-Pass, the Lower Gault expands into the six-division sequence recognisable from Paddleworth near Snodland westwards at least as far as Dunton Green. The central area of this Middle Albian trough seen in section at the outcrop occurs roughly in the position of the Sevenoaks Brick Works but it migrated slightly NE. during Middle Albian times. At Sevenoaks, the top of the Folkestone Beds contain developments of soft sandstone in regular beds. This is overlain by a comparatively thick development of the mammullatum Zone sediments. The top of lyelli Subzone and the lower part of the spathi Subzone are represented by fine clays in contrast to glauconitic clays or loam at Ford Place on the one side and at Dunton Green on the other. The overlying ‘ upper dentatus-spathi nodule bed’ contains an ammonite assemblage identical to that seen in all sections from Parsons Corner, Snodland, to the Shere By-Pass. The remainder of the Lower Gault Divisions at Seven- oaks when compared with Ford Place show the offset of the trough axes towards the NE. The whole Middle Albian sequence thins from the Sevenoaks Brick Works towards Dunton Green. Further west, the eodentatus, lyelli, and spathi Subzones at least, expand and are well developed in the area between Brasted and Covers Farm west of Westerham. Unfortunately the rest of the Lower Gault is not exposed although from the Brasted well it also is expanding west of Dunton Green. This boring also demonstrates that the mammullatum Zone troughs do not always correspond to those of the Middle Albian sediments, for here the mammuillatum Zone sediments are much thicker than those to the east and west and are little condensed. In the Addington Pumping Station situated 94 miles WNW. of Dunton Green the Lower Gault is of much the same thickness and probably lies near a common ridge axis, running NW. from Dunton Green. At the Buckland Sand & Silica Co’s pit together with Wray Common, at Reigate, the sequence although in general thicker and the sediments coarser, shows a similar succession to that seen at Ford Place. At Shere, however, the eodentatus, lyelli and basal spatht Subzones are again relatively well developed, but from here westwards to Farnham the information is either poor or of uncertain value. Moreover, the outcrop is faulted over much of this stretch of country. K 146 MIDDLE ALBIAN STRATIGRAPHY From the foregoing brief description, the evidence for NW. to SE. trending ridges and troughs is not conclusive, but is very strong. However, in the southern Weald and the Isle of Wight three pieces of evidence, in the writer’s opinion, tip the balance strongly in favour of the interpretation here given. The spatht Subzone sequence expands southwards from Wrecclesham to reach a known maximum thickness at Selborne. From there it thins southwards towards Nyewood, but the lithological sequence in detail remains the same. Although there is a partial facies change and the sediments are coarser in E. Hampshire and W. Sussex, the sequence in the spatii Subzone at Selborne lithologically is remarkably close to that of the Horton Clay Pit, Upper Beeding (text-fig. 14, opp. p. 42) where it is underlain by a thick development of the /yelli Subzone. Yet this sequence at Horton Hall is quite different to that seen at Storrington where the lyelli Subzone sediments have not been proved and if present at all are very thin and pebbly. In the opposite direction, at Hassocks, the eodentatus and lyelli Subzones sediments are still well developed but are grittier and more glauconitic and here as at Storrington the Gault rests upon an ‘ [ron-grit’ which forms the indurated top of the sands of the Folkestone Beds. At Horton Hall, however, the tardefurcata Zone is represented within clays and loams, totally different to that of Hassocks and Storrington. Along the WNW.-ESE. trending outcrop at the base of the South Downs from Storrington to Petersfield, the Gault rests upon the ‘ Iron-grit’ (Kirkaldy 1935), below which are normal loose sands of the Folkestone Beds. This sequence is seen at Portsdown where the pre-Gault Lower Cretaceous sediments are greatly attenuated. This area in which the ‘Iron-grit’ is present at the base of the Gault marks a long swell on the pre-Middle Albian sea-floor which apparently increased in amplitude towards the ESE. (p. 34). The sequence on the other side of the trough at Hassocks has already been mentioned, and from what little is known of the Lower Albian sequence near Eastbourne, and the Middle Albian sequence at Ringmer, the trough extended ESE. from Upper Beeding towards Eastbourne. The sedimentation remains very thick along this axis and if one projects the line through Selborne into Wiltshire it again coincides with a broader area of thick dentatus Zone sedimentation. On the other, southern, side of the Storrington-Portsdown swell the lithological sequence in the eodentatus, lyelli, and spatht Subzones in the Isle of Wight is totally different from that of the Ringmer-Selborne trough. It is possible therefore, that yet another WNW.-ESE. trending trough exists in the English Channel and which includes the Isle of Wight. Both the mammillatum Zone sequence and the Lower Gault increase in degree of representation towards the southern part of the Island. The diachronous base of the Gault along the Dorset Coast can be explained if one considers this line to be a diagonal section across the trough, the iutermedius Sub- zone sediments in the Charmouth area being near the southern bounding ridge which may have flanked a positive area in view of the sequence in the Pays de Caux. In the E. and NE. part of the Weald the axes of the parallel ridges and troughs trend as far as it is possible to judge in a NW. to SE. direction and they are with the possible exception of the Kent Coalfield fairly closely set and linear (text-fig. 52). The apparent opening-out of the troughs in the northern Weald W. of Dunton Green IN THE ANGLO-PARIS BASIN 147 is due partly to the fact that the outcrop tends to swing more parallel to the axes. In the southern Weald the axes have swung WNW.-ESE. and the structures are more open. These structures have what is normally considered to be an Armorican trend, and the Middle Albian is the last time that such closely lineated structures are fully identifiable in the depositional environment. (c) Source of the Middle Albian Sediments Middle Albian sediments ranging in age from the eodentatus Subzone to the intermedius Subzone rest, outside the area of the Weald and the eastern part of Hampshire, the Isle of Wight and part of Purbeck, and the area extending NE. of Aylesbury, directly upon Jurassic rocks. These Jurassic rocks had been folded and faulted in the late Jurassic-early Cretaceous to becomeland. Below the London area and N. Kent the Lower Gault, when present, rests upon thin Lower Greensand which is underlain by either Jurassic or Palaeozoic rocks. The Middle Albian sea, therefore, was clearly transgressive far outstripping the depositional area of the Lower Green- sand which itself oversteps the Wealden and both of which derived their sediments from the Jurassic land area. It is evident from the cobbles and blocks included in the mammillatum Zone sediments of Kent that Palaeozoic rocks of the London Platform were by then undergoing active erosion. From the borings in N. and E. Kent there is no evidence, however, that the London Platform contributed any large quantity of sediment during the deposition of the Lower Gault. This probably consisted only of the silty fraction which is mixed with a fine clay fraction. In general as one moves west from the Kent coast the Middle Albian clays coarsen in particle size and increase in the quantity of admixed silt andsand. This is readily apparent if one compares for example in succession the sediments of the intermedius Subzones at Folkestone, Buckland, in the Winchester borings, Devizes, and on the Dorset coast in the Charmouth area. This suggests a main sediment source from the western and north western margins of the sea, and possibly also from the south in the area of the English Channel. On the coast in the Isle of Purbeck and towards Weymouth and in the Charmouth area the diachronous base of the Gault can be seen to rest directly upon extensive areas of Jurassic clays such as the Kimmeridge Clay, Oxford Clay, and the Lias (text-fig. 23). In the area of the Hampshire Basin, British Petroleum Co., borings at Bere Regis near Wareham (Dorset) and at Fordingbridge (Hants) show the Gault to rest directly upon Oxford Clay and Kimmeridge Clay respectively. Along the northern out- crop the position is much the same (text-fig. 18), with Middle Albian sediments resting upon the Lias in the far west and then eastwards upon an eroded surface of folded Jurassic sediments in which the Oxford and Kimmeridge Clays bulk large. Now this is the state of affairs within the area of the depositional basin itself already having undergone erosion since early Cretaceous times. Moreover, this is the depositional basin which extended rapidly during spathi Subzone times to its greatest known Middle Albian extent in the intermedius Subzone. Without any question the originally far greater depositional area of the Jurassic clays must have undergone K* 148 MIDDLE ALBIAN STRATIGRAPHY active erosion during this period, and the Middle Albian sea may well have extended further during later Subzones. In the writer’s opinion all the evidence points to a source in the clays of the Jurassic, west of the London Platform, for the sediment which was redeposited as the Lower Gault. A Jurassic source to the west in Wales is suggested by the work of Jones (1955 ; 348-50), and by the borings at Port More, Antrim (Robbie & Manning 1966), and Mochras, Merioneth (Wood & Woodland 1969) in which Lias is preserved. At Port More, the incomplete remnant of Lower Lias is overlain by Upper Chalk indicating a major intra-Mesozoic hiatus, the exact nature and extent of which is uncertain at present. Much the same state of affairs existed in the Paris Basin and it is an interesting fact that here also the Middle Albian sediments are coarser in the west and finer in the eastern areas of the Basin. (d) The cristatum Subzone disturbance After the commencement of the cristatwm Subzone, a major disturbance affected the whole of the Anglo-Paris Basin and adjoining areas. In fact a break in sedimenta- tion associated with erosion occurs widely throughout the Earth at about this time, and is sometimes accompanied by folding. The disturbance caused the partial planing-off of Middle Albian sediments over the whole area of the Anglo-Paris Basin. The writer considered (1960 ; 377) that the planing-off of the upper surface of the Lower Gault in southern England was due to a tilting movement up towards the west. This may be true for the eastern half of England where definite early Upper Albian faulting has been proved (Owen im press), but it is not necessarily the explanation for the southern part of the country as a whole. In France, there is some evidence of a similar tilting movement towards Morvan and Armorica. Although the effects on the sediments is readily apparent, the main cause is much more obscure and may be connected with faulting at the margin of Europe and America before the later de- velopment of the Atlantic Ocean (p. 138). Tectonic features are few in number, and there is certainly no evidence of anything but a slight broad warping of the Basin as a whole, except for the faulting mentioned above which removed Lower Gault sediments at least from the southern part of Essex. The turbulent water conditions are reflected in the nektonic fauna ; for example Inoceramus concentricus quite rapidly develops the far stronger sulcatus form, and does not revert back to a concentricus form until the varicosum Subzone when thick, little condensed sequences are seen again. On the resulting planed-off Middle Albian surface Upper Albian sediments were laid down in an entirely different pattern to that seen in the Middle Albian. More- over, there are two intergrading facies ; the Upper Greensand and the Upper Gault. This change in pattern renders meaningless isopachyte maps based on the sediments of the whole Stage (Wooldridge & Linton 1938). It appears at present that the Upper Albian depositional pattern is more closely related to that of the Upper Cretaceous. IN THE ANGLO-PARIS BASIN 149 VII. REVIEW OF THE AMMONITE FAUNA The foregoing stratigraphical account has drawn heavily upon the evidence of relative ages provided by the ammonites. For the purpose of this Bulletin the subzonal distribution of the ammonite fauna of the Middle Albian, will be considered only. Of the other stratigraphically useful fossils, some have been mentioned in the text, but the foraminifera and ostracods require careful revision based on accurate collecting. The two plates of zonal ammonites should be used in conjunction with Spath’s Monograph (1923-43). A. Description of new species In order to stabilize the new taxa used in this Bulletin, brief descriptions are given of one species of Hoplites (H.) and two species of Anahobplites. Family HOPLITIDAE Douvillé 1890 Subfamily HOPLITINAE Douvillé 1890 Genus HOPLITES Neumayr 1875 Subgenus HOPLITES Neumayr 1875 Hoplites (Hoplites) maritimus sp. nov. (PE, ayes. ga, “b) 1925a Hoplites rudis Parona & Bonarelli (pars) ; Spath : 108, pl. 8, fig. roc, d. DERIVATION OF NAME. Hopflites :—heavily armoured soldier, maritimus : — of the sea. Diacnosis. Hoplites (Hoplites) with stout well-rounded whorl section bearing coarse projecting tuberculate bullae about 10 per whorl, each buttressed by short umbilical rib stemming from umbilical suture. Each bulla gives rise to two short coarse ribs terminating above ventrolateral margin in coarse projecting clavi arranged en-echelon each side of venter : intercostal areas merging onto venter. Ribs simple to about 40 mm. diameter, thereafter there is tendency to develop occasional lautiform ribs. Above 100 mm. ornament decreases in strength. Septal suture similar to H. (H.) dentatus. TYPE MATERIAL. Holotype BMNH. C 862a (J. S. Gardner Coll.) from Bed I (v) at Folkestone. DIMENSIONS. 53 °42 ‘52 °32. Remarks. Like all species of this genus, H. (H.) maritimus shows variation among individuals. Specimens of this form are, however, common in the lower part of the spathi Subzone taking descent from the lyelli Subzone H. (H.) of the baylei- benettianus group. At the base of the Subzone the ribbing is usually simple, but higher up occasional intercalated ribs occur which produce a lautiform effect. Later still, lautiform ribbing becomes well developed producing direct transitions to H. (H.) canavarit Parona & Bonarelli of the upper part of the spathi Subzone. 150 MIDDLE ALBIAN STRATIGRAPHY When found in condensed phosphatic nodule beds, this species shows a bewildering series of morphological transitions to other coarsely ornamented species of Hoplites. Most of these transitions are more apparent than real, in that coarse members of a number of indirectly related offshoots which developed at slightly different times have been collected together en melée in the same bed. To Spath it appeared that this species belonged to Parona & Bonarelli’s Hoplites rudis but was not typical of it (1925a ; 108). H. (H.) rudis does occur in England in the upper dentatus-spathi nodule bed in the northern Weald, however, in the writer’s opinion it represents a éoarse end member of a different development of Hoplites (H.). Horizon & LocaLities. The species occurs throughout the spathi Subzone and is ubiquitous in the Anglo-Paris basin. Genus ANAHOPLITES Hyatt 1900 Anahoplites osmingtonensis sp. nov. (Pl. 1, figs. ra, b) 1925a Anahoplites mimeticus Spath (pars) ; Spath : 142. 1927. Anahoplites mimeticus Spath (pars) ; Spath : 188, pl. 17, figs. 8a, b. DERIVATION OF NAME. From Osmington, Dorset, the type locality. Diacnosis. Anahoplites of the intermedius group : discoidal, compressed, evolute, with excentric umbilicus. Umbilical wall steep in early whorls becoming rounded in outer whorl. Umbilical margin marked by faint comma-shaped bullae giving rise to faint striate ribs on gently curving whorl flank, terminating on ventro-lateral shoulders at faint clavi absent on body chamber. Venter subtabulate slightly sulcate. Suture line like A. planus, but symmetrical across venter and highly interlocked. TYPE MATERIAL. Holotype BMNH., C 68385 (T. F. Grimsdale Coll.). Uppermost spathi Subzone between Osmington Mills and Black Head, Dorset. Paratypes BMNH., C 26595 same collection, horizon, and locality as Holotype. BMNH., 37604 (Astier Coll.) condensed Middle Albian phosphatic bed, Escragnolles, Alpes Maritimes, France. DIMENSIONS. C 68385 [107] -39 25 +33 (Holotype is slightly crushed) 37004 107 -40 <28 +30 REMARKS. This species differs from Anahoplites planus (Mantell) in its marked excentric umbilicus, slightly sulcate venter which becomes broadly rounded on the body chamber, and the symmetrical arrangement of the suture line each side of the venter. The elements of the suture line are closely interlocked resembling specimens of A. planus from the cristatum Subzone. It is, however, probably not directly related to A. planus, an early mutation of which occurs in the same bed (e.g. Spath 1927 ; 188, pl. 18, figs. 7a, b), but is very near the stem from which A. grimsdalet, A. evolutus, A. intermedius, A. mantelli, A. praecox, and A. alternatus sprang. IN THE ANGLO-PARIS BASIN I51 Spath referred the paratypes of A. osmingtonensis to A. mimeticus. However, the type of A. mimeticus (BMNH. C 30535, 1925 ; 131, pl. 11, figs. 7a, b) shows that the inner whorls are strongly costate with well developed umbilical bullae quite unlike A. osmingtonensts and in fact probably does not belong to Anahoplites at all. The stratigraphical horizon of the Holotype of A. mimeticus has been discussed above (p. 47), and it is not considered here to belong to the mammullatum Zone genus Anahoplitoides (Casey 1966 ; 547-8). HORIZON & LOCALITIES. A. osmingtonensis occurs at the extreme top of the spathi Subzone both in the Osmington area of Dorset, and the Petersfield area, Hampshire (BMNH. C 35483). It is also present in the condensed spathi, intermedius Subzones assemblage of Bed 4 at the Carriére Binot, St. Florentin (Yonne), and also at Escragnolles (Alpes Maritimes). Anahoplites grimsdalei sp. nov. (Pl. 1, figs; 2a, b) DERIVATION OF NAME. After Mr. T. F. Grimsdale. Diacnosis. eP:GPsGaesS |] Os || 2< a5 i subrotundus Spath : Se [| ee ss Ee maximus J. Sowerby ~ 2 |) 8 ep oF tenuis J. Sowerby A Xen | nexe 55 33 3» subacuaria Spath . Slt DS Anisoceratidae Protanisoceras (Protanisoceras) alternotuberculatum (Leymerie) x a An barrense (Buvignier) x ae Ay nodoneum (Buvignier) x as a3 moreanum (Buvignier) xX of spp. DS ||) Oe, |] O5€ ‘ (Heteroclinus) nodosum (J. Sowerby) x F flexuosum (v’ ae x M stahamites sablieri (d’ fener, ‘ ; x spp. 4 : ‘ xX |X Turrilitidae | Proturvilitoides densicostatus (Passendorfer) . x Pseudhelicoceras argonnensis (Buvignier) 3 x 3 subcatenatum Spath . . x Binneyitidae ? Falciferella nulbournet Casey - . : x |X Desmoceratidae Puzosia (Anapuzosia) provincialis (Parona & Bonarelli) x Uhligella derancet Casey : . : 5 x 5 evugata Casey . : xX Beudanticeras laevigatum (J. de C. Sowerby) : xX] X yy sanctaecrucis Bonarelli . Exe | a HA albense Breistroffer . BS || e.< Desmoceras (Desmoceras) latidorsatum (Michelin) xX x IN THE ANGLO-PARIS BASIN Douvilleiceratidae Douvilleiceras inaequinodum (Quenstedt) clementinum (d’Orbigny) Engonoceratidae Engonoceras tvis Spath a : : Hoplitidae Cleoniceras (Cleoniceras) devisense Spath Otohoplites spp. 3? 2 cunningtoni Spath Hoplites (Isohoplites) steinmann (Jacob) = eodentatus Casey » Sppsnetr : é (Hoplites) dentatus (J. Sowerby) robusta Spath Bs », adensicostata Spath », sulcata Seitz 5 baylet Spath ap bullatus Spath . benettianus (J. de C. Sowerby) spathi Breistroffer : persulcatus Spath 4 a paronai Spath . - maritimus Owen nov. a mirvabiliformis Spath . - Aa obtusus Spath . : + pringlet Spath . > 5 os similis Spath 4 mivabilis Parona & Bonarelli vectensis Spath . . : BS latesulcatus Spath : 4 escragnollensis Spath yudis Parona & Bonarelli BA dorsetensis Spath canavarit Parona & Bonarelli uf canavartiformis Spath 45 pretethydis Spath Fe dentatifornris ekg SPp- ” Pel Anahoplites osmingtonensis Owen noy. grvimsdalet Owen nov. . evolutus Spath mimeticus Spath intermedius Spath mantellt Spath praecox Spath : alternatus (Woodward) planus (Mantel!) » compressa Spath » ~mflata Spath p x discoidea Spath ; » sulcata Spath . C 5 » &vacilis Spath . 5 F PA A WM OM A A A AA “Anan Analanalala’ VA A A PM MOM an naw A Po 4 A OA A WA'PA p4 PA PA vA bd bd bd al 354 MIDDLE ALBIAN STRATIGRAPHY oo a 3 dS Oe ae Anahoplites splendens (J. Sowerby) : : OG DS 12S Ee@ HOS, || OS “e pleurophorus Spath , : é X 35 daviest Spath 4 x 55 » ovnata Spath dS a » elegans Spath , x ce Sph 4. a : : 5 : x Dimorphoplites niobe Spath . P ‘ : oD I-45) | 9.< a doris Spath PXS a | ex Ce pinax Spath . Xp| X a », elegans Spath xX a biplicatus (Mantell) Xp) | See ee “8 hilli Spath x a perelegans Spath xX ee crassa Spath , ipae 80 parkinsont Spath DS 126 || ES aS tethydis (Bayle) . xX |X is », Spath non Bayle D1] D8 re glaber Spath. 4 Dall ee chloris Spath GRE Euhoplites subtabulatus Spath 55 pricei Spath xX |X oe lovicatus Spath aX 2S [2S |] 2s Ss subtuberculatus Spath SHES EXC |e 5 aspasia Spath =, - XS) EXE |/PXE 5 Xe A microcevas Spath , 2) Sail 3S, |] BS Ag meandrinus Spath x sf cantianus Spath xX 55 bilobus Spath x oF beaneyi Milbourne de oF truncatus Spath xX |X » a5 quadrata Spath S| OS de lautus (J. Sowerby) DG Ds€ NB », duntonensis Spath PSE 2S ie nitidus Spath XK |X Ap opalinus Spath . xX |X 5 proboscideus (J. Sowerby) SSeS ” intermedia Spath xX |X ” bucklandi Spath ee Lyelliceratidae Lyelliceras camatieanum (d’Orbigny) ‘ , x fs pseudolyelli (Parona & Bonarelli) xX a5 hirsutum (Parona & Bonarelli) x Be hubevianum (Pictet) x a lelli (d’Orbigny) : x ” vadenaci (Pervinquiere) x ; a cotteri Spath x ; gevreyt (Jacob) xX Brancoceras (Brancoceras) senequieri (V’ Orbigny) x - 7 55 versicostatum (Michelin) x ” rr spp. ; . , x | xX IN THE ANGLO-PARIS BASIN 155 Eubrancoceras (Eubrancoceras) aegoceratoides (Steinmann) x ts fs crickt Spath SP 2:€ a5 3 spp. . . EXE ilies lhe Ne Nees Mojsisovicsiidae Oxytropidoceras evanst Spath . ‘ ‘ x Bs voissyanum (d’Orbigny) . De 33 mivapeiianum (d’Orbigny) oe 5 cf. carbonarium (Gabb) . x 3 Soh e P 5 DPSS Mojsisovicsia delaruet (d’Orbigny) ‘ x ff 56 compressa Spath xX 5 subdelaruei Spath OS i vemota Spath xX A spinulosa Spath 5 : x os equicostata Spath : : : x Dipoloceras cornutum (Pictet) “ - . x |X A Falloticeras proteum (d’Orbigny) . 4 : VIII. 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New records of Cretaceous fossils from the Isle of Wight. Proc. Isle Wight nat. Hist. archaeol. Soc., Newport 3, 283-287. 1948. Note on two exposures of the base of the Gault in Surrey. Proc. geol. Ass., London, 59, 84-86. YounG, K. 1966. Texas Mojsisovicziinae (Ammonoidea) and the Zonation of the Fredericks- burg. Mem. geol. Soc. Am., Washington 100, i—viii, 1-225, pls. 1-38. ZAKHARIEVA-KOVATCHEVA, K. 1957. Palaeofaunistic Studies and Stratigraphy of the Albian in Bulgaria (In Russian). God. sof. Univ., Sofiya 50, 209-286, pls. 5-37. H. G. OwEn B.Sc., Ph.D., F.G.S. Department of Palaeontology British Museum (NATURAL History) CROMWELL Roap Lonpon S.W.7 >) PLATE 1 Anahoplites osmingtonensis sp. nov. Fics. 1a, b. Lateral and peripheral views of holotype (BMNH. C 68385) X 1. Uppermost spathi Subzone, between Osmington Mills and Black Head, Dorset. Anahoplites grimsdalei sp. nov. Fics. 2 a, b. Lateral and peripheral views of holotype (BMNH. C 31702) X 1. Uppermost spatht Subzone, between Osmington Mills and Black Head, Dorset. Hoplites (Hoplites) maritimus sp. nov. Fics. 3 a, b. Lateral and peripheral views of holotype (BMNH. C 862a) X 1. Spathi Sub- zone, Lower Gault Bed I (v), Folkestone, Kent. ee Bull. Br. Mus. nat. Hist. (Geol.) Suppl. 8 PLATE 1 PLATE 2 Dentatus Zone Indices Hoplites (Isohoplites) eodentatus Casey Fics.1a,b. Lateral and peripheral views X 1 of an example from Bed 1, eodentatus Subzone, Coney Hill Sand pit, Tandridge, Surrey. (BMNH. C 76480) Lyelliceras lyelli (d’Orbigny) Fics. 2a,b. Lateral and peripheral views X 1 of an example from Division 2 (iv), lyelli Sub- zone, Horton Clay Pit, Upper Beeding, Sussex. (BMNH. C 76481) Hoplites (Hoplites) spathi Breistroffer Fics. 3 a,b. Lateral and peripheral views X 1 of a late mutation from Bed 4, upper part of the spatht Subzone, Buckland Sand & Silica Co. pit, Reigate, Surrey. (BMNH. C 76483) Hoplites (Hoplites) dentatus (J. Sowerby) Fics. 4a, b. Lateral and peripheral views X 1 of a late mutation from the same bed and locality as Fics. 3 a, b. (BNMH. C 76482) (All specimens author’s coll.) Bull. Br. Mus. nat. Hist. (Geol.) Suppl. 8 PLATE 2 PLATE 3 Loricatus and Lautus Zone Indices Euhoplites loricatus Spath Fics. 1a,b. Lateral and peripheral views X 1 of a late form from Division 5 (ii), meandvinus Subzone, Sevenoaks Brick Works, Otford, Kent. (BMNH. C 76484) Anahoplites intermedius Spath Fics. 2 a,b. Lateral and peripheral views X 1 of a body chamber fragment from Division 3 (iv), intermedius Subzone, same locality as Fics. 1 a,b. (BMNH. C 76485) Dimorphoplites niobe Spath Fics. 3 a,b. Lateral and peripheral views X 1 of an example from 4 inches below the top of Bed III, niobe Subzone. Folkestone, Kent. (BMNH. C 76488) Mojsisovicsia subdelaruei Spath Fic. 4. Two immature crushed individuals in a block of clay from 2 feet 2 inches above the base of Division 4, subdelaruei Subzone, Sevenoaks Brick Works, Otford, Kent. (BMNH. C 76486) Euhoplites meandrinus Spath Fics. 5 a, b. Lateral and peripheral views X 1 of a typical fragment from Bed IV (iii), meandrinus Subzone, Folkestone, Kent. (BMNH. C 76480) Euhoplites nitidus Spath Fics. 6 a,b. Lateral and peripheral views X 1 of an example from Bed V, nitzdus Subzone, Folkestone, Kent. (BMNH. C 76490) Euhoplites lautus (J. Sowerby) Fics. 7a,b. Lateral and peripheral views X 1 of a wholly septate phosphatic steinkern from the condensed ‘ /autus Zone nodule bed’ Division 6, Sevenoaks Brick Works, Otford, Kent. (BMNH. C 76487) Anahoplites daviesi Spath Fics. 8a,b. Lateral and peripheral views X 1 of an involute form from the upper part of Bed VII daviesi Subzone, Folkestone, Kent. (BMNH. C 76491) (All specimens author’s coll.) PLATE 3 Bull. Br. Mus. nat. Hist. (Geol.) Suppl. 8 —_ ‘4 +4 A LIST OF SUPPLEMENTS TO THE GEOLOGICAL SERIES Pane OF THE BULLETIN OF a, THE BRITISH MUSEUM (NATURAL HISTORY) = 1. Cox, L. E, Jurassic Bivalvia and Gastropoda from Tanganyika and Kenya. ae Pp. 213; 30 Plates; 2 Text-figures. 1965. £6. ne 2. Et-Nacecar, Z. R. Stratigraphy and Planktonic Foraminifera of the Ue > Cretaceous—Lower Tertiary Succession in the Esna-Idfu Region, Nile Yay Egypt, U.A.R. Pp. 291; 23 Plates; 18 Text-figures. 1966. {10. 3. DAveEy, R. J., Downtz, C., SARGEANT, W. A. S. & WiLtiams, G. L. Studies. on Mesozoic and Cainozoic Dinoflagellate Cysts. Pp. 248; 28 Plates, 64 Text R figures. 1966. {7. 3. APPENDIX. DAVEY, R. J., DowniE, C., SARGEANT, W. A. S. & Wittams, G L Appendix to Studies on Mesozoic and Cainozoic Dinoflagellate Cysts. Fp. 24. 1969. 16s. 4. E.tiott, G. F. Permian to Palaeocene Calcareous Algae (Dasycladaceae) of the Middle East. Pp. 111; 24 Plates, 17 Text-figures. 1968. £5 2s. 6d. “e 5. Ruopves, F.H.T., Austin, R.L.& Druce,E.C. British Avonian (Carboniferous) Conodont faunas, and their value in local and continental correlation, et. 31 31 Plates, 92 Text-figures. 1969. 11. — 6. Cuitps, A. Upper Jurassic Rhynchonellid Brachiopods from Northwestern Europe. Pp. 119; 12 Plates, 40 Text-figures. 1969. {£4 I5s. iS 7. Goopy,P.C. Therelationships of certain Upper Cretaceous Teleosts with special as reference to the Myctophoids Pp. 255; 102 Text-figures. 1969. {610s. x PRINTEDINGREATBRITAINBYALDEN &MOWBRAYLTD ATTHEALDEN PRESS, OXFO! : at "OF THE FAMILY /ACHYLEBERIDIDAE FROM _ WEST PAKISTAN ee seu aa HISTORY) Supplement 9 6 ee ohn beater . i 4 EARLY TERTIARY OSTRACODA OF THE FAMILY TRACHYLEBERIDIDAE FROM WEST PAKISTAN te A eee, 18\N'4 QADEER AHMAD SIDDIQUI University of Leicester 42 Plates, 7 Text-figures BULLETIN OF THE BRITISH MUSEUM (NATURAL HISTORY) GEOLOGY Supplement 9 LONDON : 1971 THE BULLETIN OF THE BRITISH MUSEUM (NATURAL HISTORY), instituted in 1949, 1s issued in five series corresponding to the Departments of the Museum, and an Historical series. Parts willappear atirregular intervals as they become veady. Volumes will contain about three or four hundred pages, and will not necessarily be completed within one calendar year. In 1965 a@ separate supplementary series of longer papers was instituted, numbered serially for each Department. This paper is Supplement 9 of the Geological (Palacontological) series. The abbreviated titles of periodicals cited follow those of the World List of Scientific Periodicals. World List abbreviation Bull. Br. Mus. nat. Hist. (Geol.) Suppl. © Trustees of the British Museum (Natural History) 1971 TRUSTEES OF THE BRITISH MUSEUM (NATURAL HISTORY) Issued 23 February, 1971 Price £8 EARLY TERTIARY OSTRACODA OF THE FAMILY TRACHYLEBERIDIDAE FROM WEST PAKISTAN By Q. A. SIDDIQUI CONTENTS Page I. INTRODUCTION é - - : : : : : 3 5 II. ACKNOWLEDGMENTS . - ; : - : : - - 7 III. LiTHOLoGIcaL UNITS : : : : - : : : 8 IV. SYSTEMATIC DESCRIPTIONS : : : : - : : Io Subclass Ostracoda Latreille . : 5 : ; - - 10 Order Podocopida Miiller . : : : ° : 10 Suborder Podocopina Sars : : ‘ : ; : Io Superfamily Cytheracea Baird : : : Io Family Trachyleberididae Sylvester Bradley : : 10 Genus Actinocythereis Puri. : ; Io Actinocythereis ? quasibathonica sp. nov. : : Io Genus Alocopocythere nov. : : : : 13 Alocopocythere tvanscendens sp.nov. . : ; 14 Alocopocythere rupina sp.nov. . : : : 16 Alocopocythere abstvacta sp. nov. . : : : 17 Alocopocythere coarctata sp. nov. . ‘ : c 18 Alocopocythere longilinea sp. nov. : : : 18 Alocopocythere transversa sp. nov. : : : 19 Alocopocythere vadiata sp.nov. . : : : 22 Genus “ Anommatocythere’’ Sohn . : ‘ : 23 ““ Anommatocythere ’’ laqueta sp. nov. : ; 23 “ Anommatocythere’’ confirmata sp.nov. . - 24 Genus Bradleya Hornibrook . : : : 5 26 Bradleya ? voraginosa sp. nov. . ; : : 26 Genus Buntonia Howe : : : : 5 27 Buntonia devexa sp.nov. . : ‘ : : 27 Buntonia sp. A , : : ‘ ‘ ‘ 28 Genus Costa Neviani_. : ; ; : : 28 Subgenus Paracosta nov. . : : : 28 Costa (Paracosta) declivis sp.nov. . : é 29 Costa (Paracosta) compitalis sp. nov. : : 30 Costa (Paracosta) disintegrata sp. nov. : : 31 Genus Echinocythereis Puri. é é - 31 Subgenus Echinocythereis sensu stricto : : 32 Echinocytherets (Echinocythereis) contexta sp. nov. 32 Echinocythereis (Echinocythereis) elongata sp. nov. 33 Subgenus Scelidocythereis nov. . ‘ F : 33 EARLY TERTIARY OSTRACODA Echinocythereis (Scelidocythereis) multibullata sp. nov. . . Echinocythereis (Scelidocytheveis) sp. A é Echinocythereis (Scelidocythereis) vasilis sp. nov. . Echinocythereis (Scelidocythereis) sparsa sp.nov. . Genus Gyrocythere nov. : ; . Gyrocythere exaggerata sp. nov. Gyrocythere parvicarinata sp. nov. Gyrocythere grandilaevis sp. nov. Gyrocythere mitigata sp. nov. Gyrocythere perfecta sp. nov. Genus Hermanites Puri Hermanites cracens sp. nov. Hermanites scopus sp. nov. Hermanites palmatus sp. nov. Genus Occultocythereis Howe . Occultocythereis interrupta sp. nov. Occultocythereis sp.A Occultocythereis spilota sp. nov. Occultocythereis peristicta sp. nov. Occultocythereis indistincta sp. nov. Genus Patagonacythere Hartmann Patagonacythere ? nidulus sp. nov. Genus Phalcocythere nov. - Phalcocythere horrescens (Bosquet) Phalcocythevre improcera sp. nov. Phalcocythere rete sp. nov. Phalcocythere vetispinata sp. nov. Phalcocythere sentosa sp. nov. Phalcocythere dissenta sp. nov. Phalcocythere spinosa sp. nov. Phalcocythere sp. cf. P. spinosa Genus Quadvacythere Hornibrook Subgenus Hornibrookella Moos Quadracythere (Hornibrookella) platybomus sp. nov. Quadracythere (Hornibrookella) directa sp. nov. Quadracythere (Hornibrookella) arcana aera and Guha) Quadracythere (Hornibrookella) subquadva sp. nov. Quadracythere (H. the ae sp.A Genus Stigmatocythere nov. Stigmatocythere obliqua sp. nov. Stigmatocythere portentum sp. nov. Stigmatocythere calia sp. nov. Stigmatocythere delineata sp. nov. Stigmatocythere lumaria sp. nov. Genus Tvachyleberis Brady 5 Subgenus Tvachyleberis sensu stricto Trachyleberis (Tvachyleberis) lobuculus sp. nov. Trachyleberis (Tvachyleberis) bimammillata sp. nov. Subgenus Acanthocythereis Howe Tvachyleberis (Acanthocythereis) procapsus sp. nov. Trachyleberis (Acanthocythereis) usitata sp. nov. Trachyleberis (Acanthocythereis) pedigaster sp. nov. FROM WEST PAKISTAN 5 Trachyleberis (Acanthocythereis) postcornis sp. nov. 82 Trachyleberis (Acanthocythereis) decoris sp. nov. . 83 V. OsSTRACODA AND EARLY TERTIARY CORRELATION IN THE SULAIMAN RANGE ; é ; : 5 . 2 , 85 (a) Biostratigraphic Units ; 85 (b) Statistical Correlation of ranges of ostracod species common to the Rakhi Nala and Zao River sections : A : F 89 (c) Conclusions ‘ : i 0 - . : : : gI VI. APPENDICES : : 5 : ; ‘ j 5 ‘ 93 VII. REFERENCES . : , 95 TABLES, AND RAKHI Naa AND Zao RIVER “SECTIONS In pocket on Cover Pp. ili SYNOPSIS Ostracoda from the Palaeocene of the Sor Range and from the Palaeocene and Eocene of the Rakhi Nala, Zao River and Shpalai Khwara sections, Sulaiman Range, West Pakistan, have been examined. The family TRACHYLEBERIDIDAE has been studied in detail. It is represented by fourteen genera, four subgenera and fifty-nine species. Four new genera (Alocopocythere, Gyrocythere, Phalcocythere and Stigmatocythere) and two new subgenera (Para- costa and Scelidocytheveis) are proposed. Out of the fifty-nine species described, fifty-four are new. Two species belonging to the genus Phalcocythere one from the Paris Basin and the other from Tanzania are also described. The Palaeocene and Eocene of the Rakhi Nala section are divided into five ostracod bio- stratigraphic units. The biostratigraphic units IV and V of the Rakhi Nala are represented in the Zao River section and have almost identical ostracod faunas. The biostratigraphic unit IV of the Rakhi Nala is also represented in the Shpalai Khwara section. The Equations of Correlation between the Rakhi Nala and Zao River sections for biostratigraphic unit V (i.e. Middle-Upper Eocene) have been calculated by means of ranges of ostracod species common to the two sections. The standard errors of estimate for the Equations of Correlation have also been calculated. The boundaries between the Palaeocene-Lower Eocene, Lower-Middle Eocene and Middle-Upper Eocene in the Sulaiman Range are discussed. t. INTRODUCTION THE most comprehensive work so far published on the area is that of Eames (1952 ab). Most of his lithological subdivisions for the Eocene succession of the Rakhi Nala and Zinda Pir areas occur in the northern Sulaiman Range, i.e. in the Zao River and Shpalai Khwara sections. These can easily be distinguished on the basis of lithology and microfauna. Eames’ terminology of the rock units is therefore adopted here. Bayliss (1961) and Latif (1961 and 1964) are other recent workers who have con- tributed to our knowledge of the Palaeocene and Eocene in the Rakhi Nala section. However, they used a different terminology for the rock units to that used by Eames, and Fig. 2 shows the correlation between these workers along the Rakhi Nala section. The samples from the Rakhi Nala section examined for ostracods were the same as used by Bayliss and Latif, who worked on larger and pelagic foraminifera respect- ively. These samples were collected by Bayliss. The sample numbers as given by the collector are used in this paper. Latif altered the sample numbers after 3200 by subtracting two hundred, i.e, his sample no. 3201 is the same as collector’s no. 3401, and so on, EARLY TERTIARY OSTRACODA ° . Zao River Section 68 . Shpalai Khwara Section Rakhi Nala Section G. Sor Range Section Eocene Outcrops 32° Kandahar Y Fpl sii KARACHI lie : Outcrops of Eocene rocks of part of West Pakistan. (After Eames 1952.) Sections described are indexed. FIG.1 Correlation between Eames, Bayliss and Latif along the Rakhi Nala Eames (1952, p.162-163 ) Bayliss & Samanta (in press) Latif (1961, p. 33-36, 1964, p. 31) Thickness [Sample no. Thickness | Thickness i 6 jas used in i i j Zones Succession Succession in feet [present Succession in feet & | in feet & paper sample nos.}/samplenos. : 60 657 No ==] = |Pellatispira Beds EEE S 3666 se, |GlObigerina cf. trilocula ; BE as | ¢ 425-495 a9 [zy ——"seso__[ Chiloguembeling _victoriana] 4 | Tapti a § 80 E Set 0 FS a 3b20 eee aS 1425 34 | Hastigerina_micra Sg 4 ye = 5 Chiloguembelina aff_ martini Go = CAV-D | at Ais H70 $85 | Gatapsydrax unicavu ie =e 7 ? a2 3606 : : ; v Kirthar os (|| 2212 160 “f° |Globigerina yequaensis =e 34! 3478 No Pelagic foraminifera ig [100-4484 «| Globorotalia sp. 3 3459 1160 Globorotalia sp.4 (Ghazij ) ** Lower Eocene Lower Eocene Upper Rakhi Gaj Shales Laki Lower Rakhi Gaj Shales. (topmost portion only = Irregularis Limestone. +3667-3672 Dunghan Lower Rakhi Gaj Shales (Max pars) 775 t 3116 fo | Globigerina sp.5 S [100 38s | Globorotalia rex ealee 5 | 759 roo 38 a Globorotalia (Tr) crater S S) = Oo Globorotalia angulata 4 9 Cc 3116 8 e Gorge Beds ae 8 3115 Rani kot 9 G loro = ; at Ranikot © [553 310 |850 No Pelagic foraminifera s a mi! Venericardia Shales 95 e is Pab UPPER CRETACEOUS » Probable equivalents of Eames, 1952. **Eames, personal communication. + Danian according to Nagappa, 1959, which he regards as basal Paleocene. FIG. 2 * 2 Paleocene. Li ie i i ot A A ian OE A Gis a - ee , - — RM Reis ear ge Wiis & Somicmine: perma) "(EOL 80) aus jeeiss 0 het Beare eERS. | Tic pares : be S Kencin’ 2 top? hb a im $1 . we uzas IIe > fee 4 - TD , i , Lone nos lahat s ctiie rt indeed ge. 008, s.r ; - j c 65 i } a 7 } ri bs a ‘ 7 -— be = — ob - heme ee t | Bee aa) ( oy Spas ie a el } ' Uw O% i _—. i= tl veka ‘fi - s Ar" ; r ’ nf I . oS ‘ar ee) Mane te ers were achamen . ; : “He terol A oe _— - — 4 hos —— queer — ee i Li ofA or) k | 2onigtesrnta | es . re —- rT a aia oe ee ee ay fo ia , } . pee. | 23 ae Tblubolt onafapal Se 1 ae a py wp Sees C ow. + ee ~aiohigering P, 4 pee oa ne eet | | re " a . gs nd © ; A. ; BRL Sas aq . _ — i : — rt 4 — oa — } sd aimee = ay en eye meee 4 5 — | Sy tadragot ) 2aloriger: eh, Ga . we >t *j t a ae PAAR: | anoles mt Sg ah 1 wt ion A « pi Ty vert vy a rm ashe ‘ 7 ; ; | (op Mee oe ar Les iANRA PEO x = — + “ — at seamen oe . a ee ns TR Dis Rh nel: PART a ; : : ‘ : vein wedl Be Me | gbsf agrod 2 P 4 om ike Oa oye “eee ome Apepte a A cers FF vie ce : Db) pric oithp srionisV jay — o . — a —— _ at wt belnhinlen - panier bro oo4 S28! asnma to eindboliap Sago Novozvlqummoe> WACEE .es FY. “ , Kt ceri the yt way wi Noviw £22Ol pagodol4, of oping, somone & Ree os FROM WEST PAKISTAN 7 Samples from the Zao River and Shpalai Khwara sections were taken by S. M. Ahmed and W. A. Zuberi and those from the Sor Range section by J. A. Reinemund. All specimens with the prefix Io. are in the Department of Palaeontology, British Museum (Natural History). Those with the prefix GSP BM are in the Museum of the Geological Survey of Pakistan, Quetta. II. ACKNOWLEDGMENTS I would like to express my sincere gratitude to Professor P. C. Sylvester-Bradley for his supervision, encouragement, constant help throughout this work, and for the use of the Department facilities at Leicester University. I am greatly indebted to Dr. F. E. Eames, lately Chief Palaeontologist of the British Petroleum Company Ltd., for his help and advice on the stratigraphy, particularly that of the Sulaiman Range, and for allowing me to examine East African Eocene ostracod collections at the BP Research Centre. Thanks are due especially to Dr. E. Triebel of the Senckenberg Museum, Frankfurt a.M., for his instructions in photomicrography and for kindly permitting me to study the ostracod collection at the Museum. During my several visits to the British Museum (Natural History), I have been received with courtesy by Dr. J. P. Harding and Dr. R. H. Bate, who gave me free access to the ostracod collections under their care. In addition, Dr. R. H. Bate read the manuscript critically. I have profited from useful discussions with Professor R. A. Reyment which I had while on a study tour to Stockholm. He kindly allowed me to see his West African ostracod collection. Dr. P. Marks helped me during my stay at Utrecht and gave me free access to the van den Bold, Kingma and Keij Collections housed in the Geologisch Instituut. I should like to thank Dr. F. T. Banner (University College, Swansea) for examin- ing some of the smaller foraminifera from the Rakhi Nala and Sor Range sections ; Dr. C. G. Adams (British Museum, Natural History) for his help in identifying the genus Pellatispiva from the Zao River ; and Mr. J. A. Reinemund (U.S. Geological Survey) for the information on the Sor Range locality. For the loan of samples, I am indebted to the following : Standard Vacuum Oil Company, Karachi ; The Director, Geological Survey of Pakistan, Quetta ; Dr. I. Strachan, Birmingham University ; Dr. D. D. Bayliss, Robertson Research Ltd. I would like to acknowledge the following persons for comparative material : Mr. E. S. Pinfold, Geological Adviser of the Attock Oil Co. Ltd. ; Dr. F. E. Eames, lately Chief Palaeontologist of the British Petroleum Co. Ltd. ; Mr. I. G. Sohn, U.S.A. ; Pro- fessor A. Wood, Aberystwyth ; The Director, Oil and Gas Commission, India ; Dr. W. A. van den Bold, U.S.A. ; Dr. W. D. I. Rolfe, of the Hunterian Museum, Glasgow ; Dr. N. Grekoff, France ; Dr. R. C. Whatley, Aberystwyth ; Dr. J. E. van Hinte, Holland ; and Professor G. Ruggieri, Italy. I would like to thank the departmental technical staff at Leicester University, particularly Mr. M. Barker and Mr. G. McTurk for their assistance in photography. I am very grateful to Mrs. N. Farquharson for making the diagrams and charts. This work has been done during the tenure of a Leicester University Research Scholarship. The study tours to Frankfurt, Utrecht and Stockholm were made possible by two travelling grants from the Leicester University Research Board. 8 EARLY TERTIARY OSTRACODA III. LITHOLOGICAL UNITS Sulaiman Range. The lithological units of the Rakhi Nala section have been described in detail by Eames (1952, pp. 162-165), Bayliss (1961) and Latif (196r, p-. 32). Fig. 2 shows the succession, and the formation names give some idea of the lithology ; for a fuller description, see the authors mentioned above. The Eocene succession in the Zao River and Shpalai Khwara sections (Fig. 3) is very similar to that of the Rakhi Nala section. A detailed lithological description of rocks exposed along the Rakhi Nala, Zao River and Shpalai Khwara sections is given by means of two charts. ZAO RIVER - |SHPALAI KHWARA ; Thickness | Sample] Thickness} Sample 24210 Upper Chocolate Clays (Upper part)}| 1796 24161 24160 Upper Chocolate Clays (Lower part) | 24138 [White Mart Band —Ss=~—~—Ss—sSCiSC*dS 24133 Lower Chocolate Clays 754 | 24120 178 Platy Limestone Ce ae er 594 ee ; at least 1 at least | 24693 Shales with Alabaster 24113 pe Part_of the Eocene Succession in the Northern Sulaiman Range. FIG. 3 Tapti of Eames) Upper Kirthar ( Lower Kirthar (Kirthar ss. of Eames) ! NiO! 7, BEsx. ‘P/O S*EeD Middle Eocene Upper Eocene Eoc Lr Sor Range. Samples were collected from the “‘ Claystones ”’ which are overlain by fifty feet of conglomerates. The Ghazij Shales overlie the conglomerates. A chart showing these lithological units is given (Fig. 6), and a detailed succession is given in Appendix 1. “ The locality is in Lease 58 on the north slope of the Sor Range, about eight miles by road east of Quetta (Survey of Pakistan Topo.Sheet No. 34 N/4, co- ordinates 30° 11'20” N., 67° 10’ E, grid reference P 125210). Samples were collected from a road cut along the main access road that crosses the lease approximately parallel with the outcrop and along the contour of the slope ; structurally the locality FROM WEST PAKISTAN 7 ial (uZqnz Bg Pp2WYY 42}}y7) S2a}dwWDS 0} 42}21 S}oyxODIq Ul S4dquINN ‘SUO!I}DVS DIDMYY !ID]|DGYS PUD J2AIY ODZ 24} Jo dD- iSS S2\IW co et a ann 2 e