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APR # «M

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L161— O-1096

13

.4-

THE NATURE AND ORIGIN OF
CONE-IN-CONE STRUCTURE

BERTRAM G. WOODLAND

N
M

.4

FIELDIANA: GEOLOGY

VOLUME 13, NUMBER 4
Published by
CHICAGO NATURAL HISTORY MUSEUM
MARCH 6, 1964

GEOLOGY LIBRARY

THE NATURE AND ORIGIN OF
CONE-IN-CONE STRUCTURE

BERTRAM G. WOODLAND

Curator of Igneous and Metamorphic Petrology

FIELDIANA: GEOLOGY

VOLUME 13, NUMBER 4

Published by

CHICAGO NATURAL HISTORY MUSEUM

MARCH 6, 1964

Library of Congress Catalog Card Number: 6^-18635

PRINTED IN THE UNITED STATES OF AMERICA
BY CHICAGO NATURAL HISTORY MUSEUM PRESS

55-
v.3

CONTENTS

PAGE

Abstract 189

I. Introduction 190

II. General occurrence of cone-in-cone 193

III. Description of cone-in-cone specimens 194

1. Woodland Valley, Parke County, Indiana 194

2. Dotson's Branch, Parke County, Indiana 204

3. South Trumpet Valley, Parke County, Indiana 210

4. Trumpet Valley, Parke County, Indiana 210

5. Coal Creek, Fountain County, Indiana 211

6. Old mine dump, Duee Hollow, Parke County, Indiana . . . 213

7. Montgomery Creek, Parke County, Indiana 215

8. Barren Creek, Parke County, Indiana 218

9. Town of North East, Pennsylvania 219

10. Concretion, North East, Pennsylvania 222

11. Elk Creek, Girard, Pennsylvania 225

12. Concretion, North East, Pennsylvania 226

13. Judique Interval Brook, Cape Breton Island, Nova Scotia . . 230

14. Southwest Mabou River, Cape Breton Island, Nova Scotia. . 230

15. Concretion, Smithville, Oklahoma 235

16. Calcite lenses, Big Pond Creek, Parke County, Indiana . . . 237

17. Calcite vein, Trumpet Valley, Parke County, Indiana .... 237

18. Calcite lens with trilobite Elrathia kingii, Deseret, Utah . . . 238

19. Trilobite, Argentina 243

20. Ptychoparid trilobite in calcite concretion, Gibson Lake,

Teton County, Montana 244

21. Calcite lens, Cedar Bluff , Alabama 245

22. Concretion with trilobites; Cabrieres, Herault, France .... 246

23. Calcite veins, Fleurant Point, Quebec 247

24. Coned calcite veins in black shale, Cunningham Brook,

New Brunswick 251

25. Calcite veins, one mile northwest of Myton, Duchesne County,

Utah 257

26. Tracy, Iowa 259

27. Kentucky 261

28. Ohio Shale, Cooper's Hollow, Ohio 262

29. Cone-in-cone, north of Greybull, Wyoming 263

30. Needles Peak, Big Bend region, Texas 265

31. Pottery Hill, Ottawa, Illinois 266

32. Pottery Hill, Ottawa, Illinois 267

187

188 CONTENTS

PAGE

33. Jubilee Creek, Peoria County, Illinois 269

34. Specimen of unknown origin 269

35. South of Lovell, Wyoming 269

36. Fairburn, South Dakota 271

37. Concretions near Myton, Duchesne County, Utah 271

38. Salina, Kansas 273

39. Milan, Ohio 274

40. Dudley, England 274

41. Black Hills, South Dakota 274

42. Raton, New Mexico 274

43. Specimen of unknown origin 275

44. Specimens of unknown origin 275

IV. Chemical composition 275

V. Grain orientation 277

VI. Previous views on cone-in-cone structure 279

VII. Discussion of literature 286

VIII. Results of this study — the origin of cone-in-cone and discussion of

requisite conditions for its formation 288

References 301

The Nature and Origin of Cone'in'Cone Structure

ABSTRACT

The descriptive term "cone-in-cone structure" should be applied
only to those occurrences in which the matrix is composed of an im-
pure fibrous carbonate mineral (usually calcite) and in which a con-
ical structure is made evident by the disposition of included dust or
laminae of argillaceous material. Many examples are described in
detail and figured in this paper. Non-carbonate occurrences (usually
silica) showing this particular type of conical structure are to be re-
garded as replacements of original carbonate. Compaction cones in
shales, shatter cones, which occur in a variety of rock types, and
conical shear formations in coal originate quite differently from true
cone-in-cone.

Cone-in-cone structure owes its origin to the concretionary growth
of carbonate (calcite) during the very early diagenesis of the contain-
ing sediments. The muddy sediments must have attained the requi-
site physical conditions while the supply of ions and the appropriate
physico-chemical conditions for crystallization existed. The sedi-
ments must have been in a partly compacted state so that nucleation
of carbonate took place on the surfaces of lenses of clay instead of
homogeneously throughout a watery mud, as in ordinary claystone
concretions. The fibrous nature of the calcite, its orientation, and
its differential growth, which produced the corrugated, partially con-
ical clay layers so typical of cone-in-cone, are the result of the stress
field in which the crystallization took place. The stress field was
produced by the pressure of superincumbent beds — which must have
been slight because of the early diagenetic time of development —
and by the expansional force of the concretionary action itself. The
latter may also have produced in the sediment the compaction needed
for the formation of cone-in-cone structure; for example, as layers
surrounding non-coned carbonate concretions. No external source
of stress was required, but, if it had been present at the time of crys-
tallization, it could have enhanced or modified the development of
the structure. Variations in the conditions of crystallization and in
the particular physical state and thickness of the sediment permitted

189

190 FIELDIANA: GEOLOGY, VOLUME 13

differences such as cone size, cone angle, and complexity between in-
dividual occurrences. The necessity for the presence in combination
of the right conditions is what limits the appearance of cone-in-cone
structure. On the other hand, the conditions as described above are
sufficiently ordinary to explain the geographically and geologically
widespread occurrence of the structure.

I. INTRODUCTION
Types of Cone Structures

Cone structures of a number of types have been reported in rocks.
They are here classified as follows:

1. True cone-in-cone structures, developed in calcareous beds or
in concretions; these have been described for more than a
hundred years from widely distributed localities.

2. Cone structures in relatively pure calcite veins; these are
closely related to type 1 and differ mainly in their simplicity.

3. Compaction cones, formed in shale as a result of differen-
tial compaction around small columnar competent structures
(Woodland, in press).

4. Shatter cones (fig. 25), described in rocks of various litholo-
gies in cryptoexplosion structures and interpreted by Dietz
(1959, 1960, 1961, 1963) as being the result of meteorite im-
pact (e.g., at Kentland, Indiana) and by Bucher (1963) as
caused by the penetration of vapor of magmatic origin under
high pressure into the pores of the rock. In this connection
impact cones can be produced by striking a homogeneous
rock, e.g., chert, with a sharp instrument (fig. 26). (See also
Shoemaker, Gault, and Lugn, 1961.)

5. Cone-in-cone fractures in coal (of which the Museum pos-
sesses one fine example, fig. 27), described from New Zealand
and explained as due to conchoidal shearing induced by tec-
tonic stresses (Gage and Bartrum, 1942). (See also Lhoest,
1962).

6. Cone forms, preserved in siltstone and sandstone, which are
infillings of cone-shaped depressions produced in surficial un-
consolidated materials during the fall of the water table.
Recent examples are described by Shaub (1937), but he gave
no examples from consolidated rocks nor are any known to

10 mm
i 1

Fig. 25. Shatter cones in limestone, from Newton County Stone Quarry,
Kentland, Indiana (G-3639).

10 mm
i 1

Fig. 26. Impact cone in chert (G-3112).
191

192

FIELDIANA: GEOLOGY, VOLUME 13

Fig. 27. Conical shear surfaces in coal. Merthyr Tydfil, Wales (G-450).

me. (Shaub mistakenly equates the origin of slump cones
with that of true cone-in-cone structure.) Boyd and Ore
(1963), however, described patterned cones in siltstones and
suggested that they were formed by the filling of conical de-
pressions produced by upwelling currents of water in uncom-
pacted and water-saturated silt.

This paper deals only with types 1 and 2; that is, true cone-in-
cone and the related cone forms in calcite veins.

woodland: cone-in-cone structure 193

Acknowledgments

Dr. Rainer Zangerl and Dr. Eugene S. Richardson, Jr., of the
Department of Geology, Chicago Natural History Museum, first
directed my attention to the problem of cone-in-cone structure.
They were then engaged in extensive paleoecological and strati-
graphic studies in the Pennsylvanian of west-central Indiana, and
we spent some time together in the field examining and collecting
from several cone-in-cone horizons in that area. I also wish to ex-
press my thanks to them for considerable help and discussion of
problems during the course of the study and of the writing of the
manuscript.

Many colleagues aided by the gift of specimens: Dr. David L.
Dineley, University of Ottawa; Dr. Allison R. Palmer, United States
Geological Survey; Mr. Jay Wollin; Miss Carole Stentz; Mr. Neal H.
Brown; Mrs. June Zeitner; Mr. Harold Martin, Museum of Geology,
South Dakota School of Mines and Technology; and Mr. Joseph
Choate, Chicago Natural History Museum. Dr. Robert H. Deni-
son, Department of Geology, Chicago Natural History Museum,
lent specimens he collected in Quebec and New Brunswick, and
Dr. John Clark of the same department made available specimens
from Utah. Drs. Zangerl and Richardson also collected specimens
especially for this study.

The following Antioch College students aided in various ways in
the laboratory : Douglas Gilbert, James Martin, David Kuder, Fred-
erick Echelmeyer, and Miss Selma Wiegner.

Some of the photographs shown in the text figures are the work
of Mr. John Bayalis and Mr. Homer Holdren, of the Museum's
Division of Photography. Figure 27 was made by Mr. Matthew
Nitecki, of Walker Museum, University of Chicago. Dr. Tibor
Perenyi helped in the drawings of figures 80-83. The invaluable
aid of Mrs. Evelyn Shahroch, who typed several drafts of the manu-
script, is also acknowledged gratefully, as is the assistance of my
wife, Dr. Mary Woodland, who read the manuscript and suggested
many improvements.

II. GENERAL OCCURRENCE OF CONE-IN-CONE

Cone-in-cone structure has been described from many areas of
the United States and Europe and in beds ranging in age from Pre-
cambrian (Tanton, 1931, p. 42) to Tertiary. It is reported as occur-

194 FIELDIANA: GEOLOGY, VOLUME 13

ring as lenticular calcareous beds of less than one inch up to about
six inches in thickness. It occurs in shales and associated with shales
and beds of sandstone (Gresley, 1894), as thin calcite veins in
shales (Richardson, W. A., 1923), as layers on the upper and lower
surfaces of concretions or actually comprising part of concretions,
and as calcite veins separating the upper and lower impressions of
trilobites and a fossil fish (Brown, 1954).

III. DESCRIPTION OF CONE-IN-CONE SPECIMENS

I collected specimens from three localities in Indiana and two in
Wyoming. In these cases care was taken to mark the upper surface
of the cone-in-cone layers. In addition a wide variety of examples
has been studied from the collection in the Department of Geology,
Chicago Natural History Museum, and from specimens provided by
colleagues during the course of the work.

Although cone-in-cone structure has often been described in geo-
logical literature, salient features of the specimens studied, particu-
larly those features that have a bearing on the genesis of the rock
and its structure, are described here.

1. Woodland Valley, Parke County, Indiana
(G-3546-52, G-3557)1

MACROSCOPIC STRUCTURE

These specimens were collected from the bed of a stream in the
Logan Quarry limestone member of the Staunton formation (Penn-
sylvanian).2 The cone-in-cone layer is a thin but variable layer of
about 23-24 mm. thickness. It is overlain by a richly fossiliferous
bed some 13 mm. thick, composed of the shells of marine organisms
such as molluscs, brachiopods, crinoid ossicles, and bryozoans. The
shells are frequently whole, and spines are sometimes still attached
to productids, indicating that the deposit probably represents a
fauna that has suffered little transport.

Some of the shells have been replaced with pyrite. Below the
cone-in-cone layer are dark blue-gray calcareous shales with occa-
sional small shell fragments. Close inspection of the shale shows

1 Numbers preceded by G, P, and Li refer to specimens in the collection of the
Department of Geology, Chicago Natural History Museum.

2 Location and stratigraphic details of the Indiana cone-in-cone specimens are
contained in Zangerl and Richardson (1963).

WOODLAND: CONE-IN-CONE STRUCTURE

195

4 mm

Fig. 28. Polished vertical section of cone-in-cone layer and overlying fossil
breccia showing the cones interrupted by a vertical tubular plug of different lithol-
ogy. Woodland Valley, Parke County, Indiana (G-3546).

that it is, in part, highly calcareous and contains cones, the largest
of which is about 10 mm. high (G-3557). Unfortunately, these latter
were not observed in the field and the specimen was not oriented.

The contact between the cone layer and the fossil layer is sharp
but irregular, and some lenses of calcilutite and fossil fragments
occur below the contact with cones above them. The cone layer
itself contains only an occasional fossil fragment. The cones are
not readily apparent, but partial cone surfaces can be seen on verti-
cal fracture surfaces. The cone height varies from about 4.5 to
14.4 mm., averaging about 11.3 mm., and the cone angle varies from
38° to 45°, with the point directed upward. In polished vertical
sections thin, soft, dark gray, shaly layers outline cone and partial
cone forms. Under 30 X magnification the cone surfaces are so
crowded as to interfere greatly with one another and to form thin
overlapping partially conical structures — the conic scales of Gresley
(1894). The base of the cone-in-cone layer shows some cone-cups

196

FIELDIANA: GEOLOGY, VOLUME 13

5 mm

Fig. 29. Polished horizontal surface near lower boundary of cone-in-cone
layer; dusted with alumina powder to emphasize structures. Woodland Valley,
Parke County, Indiana (G-3547).

from which the cones have fallen out; the diameters vary from
1.6 mm. to 25.6 mm. The interior surface of the cone-cups has a
characteristic corrugated surface to which adheres a layer of shaly
material. The corrugations are irregular and form incomplete hori-
zontal ledges around the cup. In vertical section the corrugations
of the shaly layers are particularly prominent in the thicker shaly
intercalations. The toothed surface of the cup is comprised of two
surfaces — small, more or less horizontal surfaces alternating with
small, nearly vertical, slightly curved surfaces. These surfaces are
shiny and appear to be slickensided, particularly the near-vertical
ones. The cone surface that lies within the cup is essentially smooth
and regular, with shale filling the toothed spaces between it and the
next superimposed cone scale. Some vertical sections cut through
columns, 4-5 mm. across, which are lighter in color than the cone-in-

WOODLAND: CONE-IN-CONE STRUCTURE

197

1

2 mm

Fig. 30. Vertical thin section of cone-in-cone layer and overlying fossil brec-
cia. Woodland Valley, Parke County, Indiana (slide no. 252).

cone matrix and which interrupt the conical clay layers (fig. 28).
The columns may extend the entire thickness of the coned layer but
others divide and come together within the coned layer and may,
in the plane of the section, terminate within the layer.

Horizontal polished surfaces show concentric arcs, arranged to
form overlapping circular series, composed of the shaly intercala-
tions (fig. 29). Laterally the cone-in-cone layer passes into a zone
where the cones are less distinct and there are many more shaly
intercalations occurring as horizontal streaks and lenses, associated
with pyrite blebs and fossils. The cone-in-cone layer thins and the
overlying fossil layer increases to 30 mm. In the field the cone-in-
cone layer appears to pinch out laterally although it could only be

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FIELDIANA: GEOLOGY, VOLUME 13

traced in one direction. However, it appears that the cones are de-
veloped within a restricted area.

Fig. 33. Vertical thin section of cone-in-cone layer showing corrugated clay
layer: a, ordinary light; b, crossed nicols. Dotson's Branch, Parke County, Indi-
ana (slide no. 267).

MICROSCOPIC STRUCTURE

Vertical sections (slide nos. 252-3). ' — The cone-in-cone layer gen-
erally has a sharp contact with the overlying shell breccia (fig. 30),
but in places it is irregular, with lenses of the latter embedded in the
coned layer and with fine-grained fibrous calcite zones in the lower
parts of the breccia (figs. 31, a, 31, b). The calcite of the coned layer
has a very characteristic structure; the grains, from about 0.025 mm.
up to 0.19 to 0.29 mm. in length and up to 0.04 mm. in width, are
more or less spindle-shaped and are aggregated into small conical
bundles all pointing to the upper surface of the layer (figs. 31, a,
32, 6) . Many minute clay particles are arranged in fine layers form-
ing partial cones in a complex meshwork (figs. 31, 32) . Thicker layers
of clay form partial cones pointing upward, with the upper surface
toothed or corrugated in a characteristic manner. These thicker
clay inclusions have variable angles with respect to the horizontal;
they are sometimes parallel to the finer smaller cones but in many
cases cut across the latter structure, although usually at a small
angle (fig. 32). This feature is identical to that shown at a higher
magnification in figure 33, although this specimen came from another

1 Slide numbers refer to thin sections in the collection of the Department of
Geology, Chicago Natural History Museum.

WOODLAND: CONE-IN-CONE STRUCTURE

201

5mm

Fig. 34. Vertical thin section of contact between coned layer and transecting
plug of different lithology that also shows microcones. Woodland Valley, Parke
County, Indiana (slide no. 253).

locality. The variability of the cone angles of the thicker clay lenses
and their discordance with the finer clay layers are produced when
the section cuts through cones at variable positions; some, for ex-
ample, are through the axis while others more commonly are tan-
gential. The small cones give the appearance of greater uniformity
because their small size produces an average overall effect of a cut
through the axial zone of the individual cones. It is the thicker clay
layers that form the macroscopic cones. The calcite fibres tend to
have a vertical arrangement but their extinction is variable, although
at a small angle to the perpendicular. This suggests that the "c"
axes have a conical arrangement (see p. 277). The calcite adjacent
to the thicker clay lenses is more irregular in shape and arrangement
and more variable in grain size than elsewhere. The clay particles
in these corrugated layers are oriented parallel to the smooth con-
ical surface, near to the latter surface, and parallel to the more nearly
horizontal surfaces of the "teeth" in the corrugated portion. The
more or less vertical surfaces of the corrugation commonly have fine

UNIVERSITY OF

202 FIELDIANA: GEOLOGY, VOLUME 13

clay trails which pass upward into the calcite and form part of the
system of small, partially conical clay lines. An occasional lens of
coarse calcite is a fragment of recrystallized fossil shell with a thin
layer of clay on the upper surface.

A thin section of one of the plugs of lighter-colored, apparently
non-coned material shows a distinctly different texture, but an incip-
ient development of microcones is present (fig. 34). The plug is
composed of very fine grained calcite, pyrite blebs, much dispersed
clay particles and aggregations of clay, and some shell fragments.
The calcite has patches of microcones throughout, which are much
finer grained than the surrounding cone-in-cone material. The
boundary of the plug is not sharply demarcated under the micro-
scope, although on a polished surface it is very clear even under
30 X magnification. In one portion the boundary is formed of a
corrugated clay layer that is part of the normal cone-in-cone layer.
This particular plug divides and encloses a central zone of normal
cone-in-cone. The plug thus originated before the development of
cone-in-cone. Apparently it represents an intrusion of material from
above, probably as a result of the activity of burrowing organisms.
It penetrated the full thickness of original sediment that is now rep-
resented by the cone-in-cone layer, and it terminates above at the
base of the shell breccia. The appearance of the plug suggests that
at the time of its formation the cone-in-cone layer (not then coned)
had much the same thickness as it has today. The cones then de-
veloped in both the plug and the surrounding matrix as a conse-
quence of deposition and perhaps recrystallization of calcite in the
pore spaces without much expansion in thickness. Such an explana-
tion, however, is not in accord with the origin of the cone structures
in the trilobite and in the veins from New Brunswick and Quebec
(see pp. 238, 251, 247). An alternative explanation is that the in-
truded material was present in the sediment and expanded in height
along with the increase in thickness of the cone-in-cone layer and
the disruption and displacement of clay layers during the addition
and crystallization of the carbonate.

The shell breccia (fig. 31) is composed of abundant shell material,
apparently only in part recrystallized but in places replaced by mas-
sive pyrite. Original open spaces in the fossils are filled with calcite.
The interstitial material is fine-grained calcite; in part, near the top
of the cone-in-cone layer, this calcite has a fibrous texture similar to
that of the cones but much finer (fig. 31, a).

A thin section (no. 266) of a layer beneath the cone-in-cone layer
is seen to have well-developed microcones but only a few thicker

WOODLAND: CONE-IN-CONE STRUCTURE

203

Fig. 35. Vertical thin section of shale lens in coned layer below main cone-
in-cone layer; note that the cones both above and below the lens point toward
each other. Woodland Valley, Parke County, Indiana (slide no. 266).

corrugated clay cones. Much clay is present in horizontal wavy
lenses, and fossil debris is common both in the clay layers and in
the coned portions. The shell fragments usually have a clay layer
on one surface. One area of the slide contains a relatively thick lens
of fine-grained structureless calcite and clay with shell fragments
(fig. 35). The fibrous calcite around the lens has well-developed par-
tial cones. The structure is confused and, in general, it is not pos-
sible to determine the direction of the apices. But, utilizing the
corrugated surface of the cones, it is seen that the cones on each side
of the lens are directed toward the lens; that is, the cones point
toward each other. This indicates a difference in direction of growth
of the calcite, presumably away from the lens.

Horizontal sections (slide nos. 254-5). — Many incomplete arcs of
clay occur in a matrix of fine-grained calcite with an occasional fossil
fragment and pyrite grains (fig. 36) . The calcite is 0.012 to 0.05 mm.
across and under conoscopic observation the "c" axes are seen to be
nearly vertical and to lie, as a rule, within the field of view of the

204

FIELDIANA: GEOLOGY, VOLUME 13

microscope. The clay arcs are intergranular and mark the inter-
section of the partial cone surfaces with the plane of the section.

0.5 mm

■ *•*£*&'■* '' "■ )-""

Fig. 36. Horizontal thin section of cone-in-cone layer. Woodland Valley,
Parke County, Indiana (slide no. 254).

2. Dotson's Branch, Parke County, Indiana
(G-3553-56)

MACROSCOPIC STRUCTURE

This occurrence is exposed in the bed of a stream and is part of
the Holland limestone member of the Staunton formation (fig. 37).
The cone-in-cone layer passes laterally into a band containing con-
cretions. The cones appear to be limited to a zone of about four feet,
measured across the stream bed.

The cone-in-cone layer has a maximum thickness of about 62.4
mm. Above it is a rubbly limestone with many brachiopod shells
and below it is shale. The cones are well defined, with lineations
from peak to base formed by bundles of fine calcite needles. The
cones point to the original upper surface of the bed (fig. 38). The

Fig. 37. Cone-in-cone layer (knife 90 mm. long). Dotson's Branch, Parke
County, Indiana.

Fig. 38. Polished vertical section of cone-in-cone layer showing corrugated
cone cups in lower center and right. Dotson's Branch, Parke County, Indiana
(G-3554).

205

206

FIELDIANA: GEOLOGY, VOLUME 13

2mm

Fig. 39. Polished vertical surface etched with dilute hydrochloric acid to
bring out corrugated conical clay layers and microcones. Dotson's Branch, Parke
County, Indiana (G-3553).

maximum height of the cones is about 36.5 mm., but the height is
usually about 29.0 mm. The cone angle of one specimen measured
near the peak is about 30°; just below the middle it is 52° and at the
base 106°. No single cone or partial cone extends from the base to
the top of the layer, but a series of cone-in-cones around a common
axis does extend the entire thickness. Shaly intercalations are well
developed and define the cones (fig. 39). In addition to the thicker
layers there are many finer conical or partially conical inclusion lay-
ers; the clay material is also aggregated into len tides only partly
related to the conical structure. The cone-cups exhibit well-marked
corrugations that give the clay insertions a toothed or zigzag appear-
ance on their outer conical surface. The corrugated surface is com-
prised of near-vertical surfaces (1.48 mm. high, in one example near
the base) and of surfaces (2.27 mm. broad) that dip outward from
the cone axis at about 108° to 110°.

WOODLAND: CONE-IN-CONE STRUCTURE

207

5 mm

Fig. 40. Polished vertical section of cone-in-cone layer showing fine horizon-
tal banding. Dotson's Branch, Parke County, Indiana (G-3553).

MICROSCOPIC STRUCTURE

Vertical section (slide no. 267). — The microscopic structure is
identical to that of the Woodland Valley specimens. Near the base
of the cone-in-cone layer there occurs a fine banding which on a pol-
ished surface appears as a series of slightly undulating lighter- and
darker-colored bands 0.14 to 0.28 mm. wide (figs. 40, 41). Thicker
corrugated conical clay layers cross the bands, with slight displace-
ment (e.g., 0.18 mm. in one case) of the bands at these intersections
(fig. 40). The bands are the result of relatively increased concen-
trations of clay — particularly in the apices of the small, partially
conical, clay laminae forming microcones — alternating with zones
with relatively less clay content (fig. 42). The fact that the micro-
cones occur without any change across the bands and the fact that
the bands themselves show displacement suggest that they owe
their existence to a pre-cone effect. However, the thicker corru-
gated clay cones cross the bands without interruption (fig. 40). It

208

FIELDIANA: GEOLOGY, VOLUME 13

is difficult to envisage how the clay layer could be displaced vertically
through pre-existing horizontal bands without the destruction of the

I mm

Fig. 41. Polished vertical section etched with dilute hydrochloric acid to
show nature of horizontal bands in cone-in-cone layer. Dotson's Branch, Parke
County, Indiana (G-3553).

latter in the affected zones. The bands probably originated during
the crystallization of the calcite in such a way as to cause small, local,
vertical displacement of clay particles, which produced horizontal
zones containing relatively less clay alternating with zones con-
taining relatively increased amounts. The cause of this differential
distribution of clay in these thin zones is not known, but it may
represent short interruptions or changes in the crystallization proc-
ess (see Reis, 1914, p. 288).

Small fossil fragments occur sparsely with a clay lens above
(fig. 43) . In some instances the fossil is separated from the clay lens
by a thin zone of very fine-grained fibrous calcite and has beneath
it a similar thin zone of calcite that merges into the coarser fibrous
calcite. In other instances, fine calcite between the fossil and the
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FIELDIANA: GEOLOGY, VOLUME 13

10 m m

Fig. 44. Well-developed corrugated cone cups. Coal Creek, Fountain County,
Indiana (G-3560).

3. South Trumpet Valley, Parke County, Indiana (G-3558)

Small specimens (Logan Quarry limestone member, Staunton for-
mation) collected from the stream bed are very similar to the Wood-
land Valley occurrence. Their maximum thickness is about 20.0 mm.
The cones point upward and the coned layer is overlain by fossilif-
erous rubble.

4. Trumpet Valley, Parke County, Indiana (G-3559)

A few fragmentary specimens (from below Logan Quarry shale,
Staunton formation) were collected in the bed of the stream but
they are not oriented as to top and bottom. The cone-in-cone layers
are at least 73.8 mm. thick. Cone surfaces show longitudinal stria-
tions from peak to base, while cone-cup surfaces are corrugated.
Cone angles are very acute, with angles, measured near the peak, of
25° in one case and 28° in another.

WOODLAND: CONE-IN-CONE STRUCTURE

211

10 mm

Fig. 45. Valve of Desmoinesia muricatina overlying a cone of a cone-in-cone
layer; a spine extends steeply along a conic scale. Coal Creek, Fountain County,
Indiana (G-3560).

5. Coal Creek, Fountain County, Indiana (G-3560)

One specimen from above Coal 1 1 A, Staunton formation, was
collected by Dr. Zangerl. It has a thickness of nearly 32 mm. and
the maximum individual cone height is 29.81 mm. The maximum
cone base is 33.86 mm. The cone surfaces have both longitudinal
and transverse concentric striations. The inner cone surface or cup
is irregularly corrugated, the characteristics of which are shown in
figure 44. The average cone angle of the specimen is about 68° but
it flares out toward the base so that the corresponding angle here
would be about 108°. The cones point to the surface, which con-
tains several brachiopod shells. One valve of Desmoinesia lies on
the surface (top?) at the focus of a series of conic scales. One spine
is clearly visible as being in position and was still attached to the
shell at the time of collection (fig. 45). The shell material of this
part of the valve has come away and the impression clearly shows
the point of attachment of the spine to the shell. The spine extends

Fig. 46. Corrugated surface of cone-in-cone layer; an interior surface along
which the specimen separated. Viewed toward an exterior surface, the ridges are
analogous to cone structure. One mile south of Mecca, Parke County, Indiana
(G-3843).

21mm
i 1

Fig. 47. Polished vertical section of cone-in-cone; note upper and lower lay-
ers, separated by thin intermediate zone. Conical forms are black shale, with
apices toward the interior. One mile south of Mecca, Parke County, Indiana
(G-3843).

212

WOODLAND: CONE-IN-CONE STRUCTURE 213

steeply down the surface of a conic scale for about 13 to 14 mm. and
then flattens out for a further 7 to 8 mm., occurring apparently in a
shaly intercalation between conic scales. There are a few fractures
in the spine but there has been only slight displacement. This oc-
currence indicates that the spine must have been embedded in a
matrix sufficiently strong to support it. Any differential movement
between the cones, which must have developed after the brachiopod
with its spines was emplaced, was not of a violent nature and pre-
sumably not of a shearing type. The presence of this delicate car-
bonate spine in the clay also supplies evidence that the clay is not a
residue concentrated by solution of carbonate.

6. Old Mine Dump, Duee Hollow, One Mile South of
Mecca, Parke County, Indiana (G-3843)

MACROSCOPIC STRUCTURE

As this specimen was collected from a waste heap its original
orientation is not known. It is about 18 mm. thick and is interest-
ing because both of its surfaces, which presumably were parallel to
the bedding, have irregular corrugations, somewhat like ripple-marks
(fig. 46). The corrugations have a reticulate pattern and their am-
plitude is about 2 mm. on one surface compared to 1 mm. or less on
the other. In a polished vertical section these corrugations can be
related to the partial cone structures in the specimen, which is di-
visible horizontally into three layers (fig. 47) — two outer coned layers
separated by a thin non-coned zone. One coned layer is 4 mm. thick
while the other is 12 mm. thick, and both show partial cones formed
by layers of black shale separated by calcite. Toothed surfaces of
the shale indicate that the cones of each layer point toward the in-
terior. In the intermediate zone, some 2 mm. thick, small saucer-
shaped wisps of shale lie parallel to the horizontal. As the cones
tend to occur in vertical stacks and also in discontinuous rows, the
surfaces of the specimen are corrugated. Most of the stacks of cones
have a distinct narrow axis of lighter color composed of very fine
calcite (fig. 48). The axis is actually a thin sheet axial to a short
row of related partial cones, each of which forms a trough section of
the corrugated surface (figs. 49 and 50).

MICROSCOPIC STRUCTURE

Vertical section normal to corrugations of surf ace (slide no. 825). —
The coned zone shows undulating, discontinuous, very dense shale

214

FIELDIANA: GEOLOGY, VOLUME 13

layers up to 0.28 mm. thick, forming macrocones up to 1.16 mm.
high. The outer surfaces of some of these shale layers have the

50mm
i 1

Fig. 48. Etched vertical section of one stack of cones shown in figure 47.
Note axial zone that disrupts conical sheets of black shale. Fine calcite has been
dissolved, leaving a furrow.

characteristic toothed structure. The shale is opaque even when
very thin and in this respect is similar to the Mecca Quarry shale
(Zangerl and Richardson, 1963) reported by Ashley (1899, pp. 363,
371) as occurring above the coal of this locality. The calcite between
the shale lenticles is fibrous, with fibres up to about 0.1 mm. long,
and occurs in microcones about 0.23 mm. high outlined by very fine
shale layers.

Vertical section parallel to corrugations of surface (slide no. 826). —
This section is closely similar to that above except that the macro-
cones do not exhibit the same degree of regularity. In part the shale
layers form large arcs, indicating that the section was cut tangen-
tially along a row of partial cones.

Horizontal section (slide no. 827). — Wide arcuate shale layers are
present, representing the intersections with macrocone shale layers
that actually have the form of linear troughs rather than partial
cones. Between the macrocone shale layers is the fibrous calcite that
contains arcuate sections of the partial microcones.

WOODLAND: CONE-IN-CONE STRUCTURE 215

The cone-in-cone layer probably developed at the top of the
Mecca Quarry shale when the lithology was transitional to shales of
the Velpen limestone member (Zangerl and Richardson, 1963), as
Ashley (1899, p. 363) records limestone bands and cone-in-cone in
the area where this specimen was found. Dense black carbonaceous
layers may have alternated with thin clay or silt layers (as repre-
sented, for example, in pi. 8, C, or pi. 10, F, Zangerl and Richardson,
1963). The calcite crystallized following nucleation on the surfaces
of the carbonaceous layers, and continued fibrous growth produced
the microcone and the linear macrocone structures. The time of
development would have been shortly after deposition of the black
shales when the environment had changed and the marine waters
were bearing lime in solution. The axial sheets of the partial cones
evidently controlled the development of the structure. The axial
sheets may have been fine cracks or disturbances in the original sedi-
ments before the crystallization of any carbonate but their origin
is unknown.

It is pertinent to mention here that Mykura (1960) records cone-
in-cone veins and limestone bands that have replaced coals obviously
long after deposition and coalification. The calcite replacement is
part of a process during which the coal was partly or completely
removed by oxidation. Residual coaly material and mineral im-
purities of the coal form layers outlining the cones (see Mykura,
1960, pi. VII, C). This is a special case of delayed development of
cone structure. The oxidation of the coal evidently produced con-
ditions in the residue physically suitable for cone-in-cone to form so
long as calcium carbonate was available in the circulating water.
Deposition and growth were probably synchronous with oxidation
or followed immediately or shortly thereafter.

7. Montgomery Creek, Parke County, Indiana (Li-4709)

macroscopic structure

The limestone beds comprising the Velpen member (Linton for-
mation) are dark gray and very impure, a representative seven-gram
sample containing over 36.6 per cent of insolubles. Organic content
is, however, very small, as the loss in weight on heating the residue
to 700° C. is only 3.5 per cent of the total sample and much of the
loss represents oxidation of the pyrite. Fossil fragments are abun-
dant more or less throughout the matrix but tend to be more preva-
lent in some ill-defined bands. The matrix has a general dark gray

216

FIELDIANA: GEOLOGY, VOLUME 13

MF> i

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Fig. 49. Polished horizontal surface of cone-in-cone from specimen G-3843,
shown in figures 46-48. Note that deeper troughs (analogous to cone-cups) remain.

color with streaks and lenticles of darker gray ranging in thickness
from large masses up to 10 mm. down to mere wisps just visible to
the naked eye. Pyrite is common; it replaces the shells and also
occurs as blebs throughout the matrix.

MICROSCOPIC STRUCTURE

Vertical section (slide no. 370). — The rock is very dense and its
structure remains much obscured by opaque matter even when the
section is very thin. The clay material is disseminated throughout,
obscuring the crystalline calcite base; the latter is very fine grained,
the grains rarely exceeding 0.005 mm. and usually less than 0.0025
mm. in diameter. Much of the clay is aggregated into wisps and
lenticles; in some patches these form microcones. In the better-
defined zones the cones are clear and the calcite is somewhat less

5 1.8 mm
i 1

Fig. 50. Enlarged view of the right end of the specimen shown in figure 49.
The arcuate black structures are intersections with black shale layers forming
partial cone-cups or troughs. The light-colored vertical lines are carbonate-rich
axial sheets of trough zones, each of which contains a stack of structures analogous
to cones.

217

218

FIELDIANA: GEOLOGY, VOLUME 13

Fig. 51. Vertical thin section of Velpen limestone, Barren Creek, Wabash
Township, Parke County, Indiana, showing microconed zones (slide no. 293).

charged with inclusions. The individual cones are about 0.2 mm.
in height, and the clay layers 0.008 to 0.02 mm. thick. Fibrous tex-
ture is not evident because of the fine grain size and the high clay
content. Because of the merging mass of cones it is not possible to
determine the true apical direction of any zone; the cones appear
the same in either direction and there are no corrugations of the fine
layers to help in determining the orientation. The coned patches
contain some fossil fragments and pyrite blebs. Some zones occur
on shell fragments; others grade into the rock matrix. The coned
zones pass into areas of greater clay content where incipient coning
can just be made out, thence to zones where the clay wisps have a
more crescentic shape, and finally to zones where there is no evidence
of coning or concretionary formation.

8. Barren Creek, Parke County, Indiana (Li-4708)

An etched vertical surface and thin sections (slide nos. 291-3) of
this specimen of the Velpen limestone member show the same rela-

WOODLAND: CONE-IN-CONE STRUCTURE

219

tionships of microconed zones passing into zones of incipient cones
and into areas of considerable clay material, which is finely pitted, in-

10 mm

Fig. 52. Polished vertical section of cone-in-cone showing transition zone
(upper portion). North East, Pennsylvania (G-3568).

dicating where disseminated calcite has been dissolved out. The
thin section (fig. 51) has structures identical to those described above
from Montgomery Creek.

9. Town of North East, Pennsylvania (G-94 and G-3568)

MACROSCOPIC STRUCTURE

The cones in specimen G-94 are well formed but interfere with one
another so that they are invariably only partial cones. They extend
from one surface of the specimen to a level 27.20 mm. from their
bases, where they pass into a non-coned zone that does, in part, have
a fibrous texture and a suggestion of microcones; otherwise, the ma-
terial filling in between the cone peaks appears to be a structureless
calcilutite. The projected cone angle, which is 36° at the peak, in-
creases to 104° near the base. A polished surface of a similar speci-
men (G-3568) clearly shows the shaly intercalations between the
cones, and the non-coned layer is seen to contain more or less hori-
zontal thin clay lenses (fig. 52) . Cone angles at the peaks vary from
56° to 64°.

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WOODLAND: CONE-IN-CONE STRUCTURE

221

Fig. 54. Vertical thin section of cone-in-cone layer showing corrugated clay
layers and calcite spindles; crossed nicols. North East, Pennsylvania (slide
no. 276).

MICROSCOPIC STRUCTURE

Vertical section (slide no. 276, made from G-3568). — The calcite
appears to be very fine grained with abundant clay included, much
of which is arranged into interfering conical surfaces (fig. 53, a).
Under crossed nicols, however, the section shows spindle-shaped
areas, each of which nearly extinguishes as a unit and the long di-
rection of which is more or less parallel to the cone axes (figs. 53, b,
54) . The thicker corrugated clay layers define the macroscopic cones
of the specimen. The conical surfaces all point toward the same
surface. In this direction the matrix passes into a zone where the
calcite is much more irregular, the clay content is increased, and
conical clay surfaces are absent (fig. 53, a). In the transition zone
the calcite spindles become more irregular and smaller and finally
disappear (fig. 53, b). This passage from a coned to a non-coned
layer is thus gradational under the microscope, but to the naked eye
it is a sharp line marked by a color difference on the polished surface

222

FIELDIANA: GEOLOGY, VOLUME 13

0.5 mm

Fig. 55. Vertical thin section of cone-in-cone layer showing fine horizontal
bands. North East, Pennsylvania (slide no. 276).

(fig. 52), although close examination does indeed show that some of
the cone apices pass across the contacts.

Near the boundary toward which the cones open are several thin,
faint bands caused by alternating zones of more and fewer clay in-
clusions (fig. 55). The microcones continue through these zones
without interruption. The bands are identical to those described
in the Dotson's Branch specimen.

10. Concretion, North East, Pennsylvania (G-151)

MACROSCOPIC STRUCTURE

This is a large "double-eyed" concretion 55.0 cm. long, with one
eye 35.0 cm. across and the other 28.0 cm. (fig. 56). The maximum
thickness of the concretion is 90 mm. One surface has marginal con-
centric markings apparently denoting original bedding laminae, while
the other has characteristic arc-like structures representing the clay

WOODLAND: CONE-IN-CONE STRUCTURE

223

33 mm

Fig. 56. Surface of large "double-eyed" concretion showing cone cups. North
East, Pennsylvania (G-151).

bases of partial cones. The arcs extend across the waist portion
joining the "eyes" and are concentrically arranged around the cen-
ters of the eyes. Occasionally a combination of arcs forms an entire
circle; in a few of these the complete cone has fallen out, revealing
a corrugated cone-cup. The central portion of the opposite surface
has small (up to ca. 3 mm.), circular marks caused by the bases of
incipient cones.

The coned layer of one "eye" has split from the remainder of the
concretion because of a clay parting. In section at the "waist" the
separated layer is seen to have a maximum thickness of 24 mm.,
thinning to the margins. The outer 21 mm. are coned and pass in
the interior to a non-coned layer containing much pyrite. At the
center of the "eye" the layer is 30 to 31 mm. thick. The coned layer
is concavo-convex. The internal concave surface has incomplete
concentric "steps" in the clay parting with lineated slickensides step-
ping down toward the center of the concretion. The counterpart of
this surface has a slight central swelling with slickensided "steps"
around. A vertical section of the opposite part of the concretion has
a maximum thickness of 58 mm. and is very fine grained. It shows,
in part, a weak color lamination parallel to the surface and also has
irregularly shaped zones, greenish in color, set in the purplish base
of the interior portion. The external zone, 5 mm. thick, shows very

224

FIELDIANA: GEOLOGY, VOLUME 13

faint incipient cone structures. On the inside of this zone is a 1 mm.
thick zone bearing very small clay lenses.

Fig. 57. Vertical thin section of weakly coned layer of specimen G-151, a
concretion from North East, Pennsylvania (slide no. 277).

MICROSCOPIC STRUCTURE

Specimen G-3568, already described (p. 219), is identical in ap-
pearance to the cone-in-cone layer of this large double concretion
and doubtless the microscopic structure is similar. The thinner layer
on the opposite surface of this concretion shows only incipiently de-
veloped cones on a polished surface. Under the microscope (slide
no. 277) microcones formed of lines of inclusions are visible but are
not well developed (fig. 57). The cones point toward the center of
the concretion. The coned zone passes inward to a zone where there
is increased clay, now in saucer-shaped lenses, their concave surfaces
facing the outside. This zone in turn passes into the regularly banded
interior, composed of fine-grained calcite and clay. The banding is
caused by varying quantities of the clay component. The coned

WOODLAND: CONE-IN-CONE STRUCTURE 225

pattern appears to be of very fine grain with calcite ranging from
0.008 to about 0.07 mm. but mainly between 0.015 and 0.023 mm.
Between crossed nicols, however, there are larger fan-like areas of
extinction whose orientation is related to the conical lines of clay.
The banded zone is homogeneous between crossed nicols while the
zone of saucer-shaped inclusions has clearly a transitional appear-
ance. These structures are identical with the specimen G-3568 pre-
viously described except for their poorer development.

The occurrence of a coned fabric can thus pass by transition into
a non-coned concretionary fabric. The development of the cones is
accompanied by the appearance of the coarser spindle- or fan-shaped
areas, with the orientation of the "c" axes of the calcite similar or
nearly similar. The fabric suggests that the original fine-grained car-
bonate recrystallizes during the time the conical structure is forming.
If such is the case, the cause of the recrystallization, why it should be
restricted to the outer zones of the concretion, and why one layer is
thicker and better developed than the other remain as unanswered
questions. On the other hand, the fabric of the veins described later
(p. 251) and of the Woodland Valley and Dotson's Branch specimens
does not provide evidence of recrystallization. In fact, it is difficult,
if not impossible, to see how the thicker corrugated clay cones could
be formed and consistently point in the same direction in a particular
layer by recrystallization of an existing carbonate-clay rock. It is
probable, therefore, that the calcite crystallized directly, so that ag-
gregates of minute fibres with almost the same lattice orientation
form the spindle-shaped groups so characteristic of the microscopic
structure viewed between crossed nicols.

11. Elk Creek, Girard, Pennsylvania

In August, 1963, 1 made a brief examination of cone-in-cone occur-
rences exposed in Elk Creek, three miles east-southeast of Girard, just
north and south of the Gudgeonville covered bridge. North of the
bridge the steep west bank, some 50 to 60 feet high, exposes shale of the
Conneaut Group, upper Devonian. The gray, finely laminated shale
breaks with an irregular fracture and weathers to a light brown color.
Intercalated with the shale are thin (less than 1 inch thick), harder,
siltstone bands. About five feet above the creek bed is a zone of
ellipsoidal calcareous concretions which protrude several inches from
the shale (fig. 58, a). The vertical faces of the concretions I examined
were rough fracture surfaces produced by erosion (fig. 58, 6), and these
vertical sections were approximately ellipsoidal in outline, although

226 FIELDIANA: GEOLOGY, VOLUME 13

the ends were blunt instead of smoothly rounded in some cases. All
have an upper and lower cone-in-cone layer separated by a central
non-coned layer. The cones all point toward the interior of the con-
cretion. The enveloping shale layers are curved around the concretion
but, on tracing to the periphery the layers lying on and immediately
below the concretion, some 2 inches of shale lateral to it are not trace-
able over or under it. This represents the amount of material incor-
porated into the concretion during its growth. One concretion is 30
inches across and 10.25 inches thick, with an upper coned layer of 4
inches and a lower of 3.5 inches. Another section of a concretion
(fig. 58, 6) is 40 inches in diameter with an upper coned layer of 3
inches maximum thickness, a lower of 3.25 inches, and an intermediate
non-coned layer of 2 inches.

Downstream, some 50 yards below the bridge, many cone-in-cone
concretions are exposed in the creek bed. The shale has been eroded
to reveal concretions, all at the same horizon, with variable shapes
in plan view — ellipsoidal, discoidal, and more irregular; maximum
dimension is 5 feet. They are spaced irregularly, some being as close
as 4 feet and others up to 21 feet apart.

The concretions probably represent a period of increased liminess
in the water, so that, although there was no deposition of carbonate as
a sediment, the waters circulating through the sediments just below
the sediment-water boundary became supersaturated. Deposition of
carbonate began at a number of centers and continued long enough
to produce the large coned concretions.

The detailed structure of the specimens G-3832-42 is similar in
all essential respects to the structure of those described above (G-94,
G-3568, and G-151).

12. Concretion, North East, Pennsylvania (G-638)

MACROSCOPIC STRUCTURE

The specimen is incomplete and represents approximately half the
concretion, which had broken vertically across the originally discoid
body (fig. 59). Its maximum thickness is nearly 58 mm. and its origi-
nal diameter would have been about 200 mm. In vertical section the
central portion of the concretion is horizontally bedded and contains
thin wisps of clay material horizontally arranged (fig. 60). In some
bands and patches the clay wisps are dark-colored, in others they are
buff -colored (oxidized?). The two outer coned layers taper to zero

Fig. 58. Concretions bearing cone-in-cone structure in upper and lower lay-
ers: a, two concretions exposed by weathering; b, close-up of concretion at left in
a. Elk Creek at Gudgeonville covered bridge, three miles east-southeast of Girard,
Pennsylvania.

227

228 FIELDIANA: GEOLOGY, VOLUME 13

lOmm

Fig. 59. Surface of silicified coned concretion. North East, Pennsylvania
(G-638).

thickness at the margins and have a maximum thickness in the middle
of about 17 mm. and 14.3 mm., respectively. The partial cones are
defined by buff -colored clay layers that bear the characteristic toothed
surface and form the corrugations in the cone cups visible on a frac-
tured surface. The cone apices point toward the center of the concre-
tion . The intersections of these partial cones of clay with the concretion
surfaces are marked by strongly developed arc-like furrows concen-
trically arranged, so that their concavities face toward the vertical
axis of the concretion. Toward the axis the arcs are larger and form
more nearly complete circles. In vertical section the partial cones of
clay are seen to be systematically arranged. In the thickest part of
the layers near the center they tend to form more complete cones, but
toward the periphery the part of the cone inclined from the middle of
the concretion toward the exterior is preferentially developed (see fig.
60). The acute angle formed by the clay layer with the horizontal
decreases outward from about 65° in the middle. Near the periphery
the clay layers clearly pass internally into the horizontal clay layers
of the central bedded portion of the concretion (fig. 60) .

Except for the trilobite specimens (PE-6164, P-196, and P-200) de-
scribed below (pp. 243, 246), this coned concretion is unlike any other
examples in that it is siliceous — a very fine grained, dense chalcedony.

MICROSCOPIC STRUCTURE

Vertical section (slide nos. 273-274) . — Corrugated clay layers form-
ing partially conical surfaces are well developed (fig. 61) and point

WOODLAND: CONE-IN-CONE STRUCTURE

229

Fig. 60. Polished vertical section of silicified coned concretion. North East,
Pennsylvania (G-638).

toward the central region of the concretion. The matrix is composed
of very fine silica with disseminated dust and a little fine carbonate.
There are some small thin cones of clay but they are not present
throughout the matrix.

It is considered that the concretion was originally formed of cal-
cite and later replaced by silica, with the preservation of the partially
conical clay structures but with the destruction of the microfabric.

2 mm

Fig. 61. Vertical thin section of silicified coned concretion. North East,
Pennsylvania (slide no. 274).

230 fieldiana: geology, volume 13

13. Judique Interval Brook, Cape Breton Island,

Nova Scotia (G-3586)

Dr. David L. Dineley, of the University of Ottawa, kindly made
this large concretion available. The specimen is from the Horton
Group (Mississippian) . It is about 400 mm. long, with a maximum
width of 260 mm. and thickness of 140 mm. It has a somewhat ir-
regular form, partly due to breakage and loss. Cone-in-cone is evident
in the upper and lower portions but a better understanding of the
structures can be obtained in a vertical section.

The upper coned layer has a maximum thickness of about 57 mm.
Conical clay layers are well developed and show an ordered arrange-
ment of a series of cones around common vertical axes extending the
whole thickness of the layer. An unusual feature of these cones is
that they appear to point upward and away from the central zone,
contrary to the usual arrangement. However, the corrugations of
the clay layers are on the lower surfaces, thus showing that the true
cones actually point downward toward the center of the concretion.
Etching by dilute hydrochloric acid brings the structure of the clay
into sharp relief (fig. 62) . The outer portion of the layer is composed
of fibrous calcite and there are the usual fine microcones of clay as
well as the macrocones. The axes of the cone stacks show up as a
high density zone of very fine clay in which a cone structure is barely
discernible in places (fig. 63). Radiating from these columns are the
thicker conical clay lenses forming the macrocones and also the finer
microcones set in a fibrous calcite matrix. The columns do not extend
completely to the inner margins of the coned layer. The inner part
of the coned zones passes into finer microcones with a greater quan-
tity of fine clay.

14. Southwest Mabou River, Cape Breton Island,

Nova Scotia (G-3587)

This specimen was collected by Dr. Dineley, of the University of
Ottawa, who kindly made it available to me. It occurs in the Horton
Group (Mississippian) about 6.4 miles northeast of Judique North.
It is about 80 to 85 mm. thick and is bounded top and bottom by
dark shale.

Cone-in-cone layers are prominent in the upper and lower parts,
although commonly the clay is in the form of lenses, which may be
more or less horizontal but are usually saucer-shaped. The conical
clay lenses and many of the saucer-shaped lenses bear conspicuous

WOODLAND: CONE-IN-CONE STRUCTURE

231

5 mm

i 1

Fig. 62. Polished and etched vertical section of coned concretion; cones point
downward toward center of concretion. Cape Breton Island, Nova Scotia
(G-3586).

corrugations that face the interior of the mass. The cones of both
layers point toward the center. The saucer-shaped clay lenses, how-
ever, generally are convex toward the upper and lower surfaces re-
spectively, but the presence of corrugations on the inner surfaces
shows them to be analogous to cones. A cone-cup on a fractured
vertical surface bears beautifully slickensided corrugations.

Etching of a vertical surface with dilute hydrochloric acid brings
out the structures very clearly. The lower coned zone in one etched
band is about 50 mm. thick (fig. 64); the calcite is coarsely fibrous

232

FIELDIANA: GEOLOGY, VOLUME 13

1

1.0 mm

i— 1

Fig. 63. Polished and etched horizontal section of cone-in-cone layer of con-
cretion. Cape Breton Island, Nova Scotia (G-3586).

and there are many small partial clay cones throughout the calcite
as well as the macroscopic clay cones and lenses (fig. 65). Toward
the interior the macrocones die out and the small clay cones become
very much tinier and very abundant ; consequently the clay increases
in quantity and the calcite is much finer grained. In turn this passes
to a zone about 10 mm. thick in which there are no macrocones or
microcones and the structure is homogeneous and fine-grained. The
upper coned layer is about 19 mm. thick; the calcite is finely fibrous
and the microcones are very tiny and abundant. The macrocones
are not so well developed as in the lower zone. Masses of fine pyrite
and probably sphalerite occur in the clay laminae. The cone axes

WOODLAND: CONE-IN-CONE STRUCTURE

233

3 mm
i i

Fig. 64. Polished and etched vertical section of coned concretion showing
fine-grained cone axes with cones pointing downward toward center of concretion.
Cape Breton Island, Nova Scotia (G-3587).

have a structure (fig. 64) similar to that described in the preceding
example (G-3586).

The structures present are intermediate between those of the
Cunningham Brook calcite veins, described below (p. 251), and typ-
ical cone-in-cone such as that of Woodland Valley or Dotson's Branch.
The specimen has many of the characteristics of the veins, although
on a more massive scale.

The abundant, finely dispersed clay of the axial columns repre-
sents the discrete clay layers of the cones expanded and spread
through a greater vertical distance by fine-grained calcite. The cause

234

FIELDIANA: GEOLOGY, VOLUME 13

3.0 mm

Fig. 65. Polished and etched vertical section of coned concretion showing
microcones; cones point upward toward central non-coned portion of concretion.
Cape Breton Island, Nova Scotia (G-3587).

of this difference in calcite crystallization is problematical, but it may
have been produced by a physical difference in the thin clay layers
at the time of the concretionary growth, for example, as a result of
small circular vertical disturbances caused by burrowing organisms
or more likely by gas bubbles. (The columns are much more prev-
alent in the upper coned layers.)

The central zone, some 29 mm. thick, is fine-grained and contains
much fine, disseminated, structureless clay. This passes into a lower
coned layer about 54 mm. thick, the inner part of which is similar
to that of the upper coned layer. The outer portion is again com-
posed of fibrous calcite and contains microcones of clay. The macro-
cones, however, are considerably less well formed than those in the
upper coned layer. The clay is present mainly as relatively thick,
irregular lenses. Pyrite aggregates occur in both coned and non-
coned portions of the concretion.

WOODLAND: CONE-IN-CONE STRUCTURE 235

15. Concretion, Smithville, Oklahoma (G-3610)

Mr. J. Choate kindly supplied this specimen, which he collected
as a loose piece from a road cut 5 miles southwest of Smithville.
It is from the Ten Mile Creek formation (Mississippian).

Honess (1923, pp. 192-193) describes the occurrence of cone-in-
cone in the southern Ouachita Mountains as follows: "These cone-
in-cone concretions are lenticular masses one foot to three feet across,
by 3 to 6 inches thick, ordinarily, and occur in beds of black shale
in close proximity to each other in the layers where they occur. The
concretions have a central, horizontally schistose core of dark bluish
gray, siliceous-argillaceous, finely granulated material out of which,
all about this central mass, normal to the surface curvature, spring
myriads of the cone-in-cones, growing outward and forming a shell
one to two centimeters thick."

MACROSCOPIC STRUCTURE

Specimen G-3610 is a portion of a concretion about 100 mm. thick
and elliptical in section. The central portion is fine-grained, dense, and
structureless, possessing thin, irregular, silty, micaceous lenses and
carbonaceous smears. On this core are two unequal, coned, concavo-
convex layers, one up to 40 mm. thick, the other about 16 mm. The
partially conical shale lenses are relatively thick, with carbonate con-
ical scales separating them. The shale layers flare out toward the
surface of the concretion and form layers nearly parallel to the convex
outer surface. This surface shows the typical arc forms of the partially
conical shale layers. The cones point toward the interior of the con-
cretion, and just within the inner border of the layer there is a zone,
ca. 2 mm. thick, which has well-defined, small, wavy shale lenses and
which, as the shale lenses become finer, passes imperceptibly into
the central region of the concretion.

MICROSCOPIC STRUCTURE

A thin section (slide no. 290) of the outer zones shows that about
5 mm. from the inner border of the coned layer the concretion is
composed of wavy shale lenses about 0.02 to 0.04 mm. thick sepa-
rated by "augen," 0.04 to 0.08 mm. across, of quartz or chalcedony
and a little carbonate, whose grain size is mainly 2 to 5 microns but
with some grains up to 12 microns across (fig. 66) . Toward the coned
zone is a narrow transition zone where the wavy shale lenses are a
little thicker (up to 0.07 mm.) and the "augen" are a little larger,

236

FIELDIANA: GEOLOGY, VOLUME 13

I mm

Fig. 66. Vertical thin section of coned concretion; non-coned central zone at
bottom of photograph; coarser and purer calcite separates partially conical layers.
Near Smith ville, Oklahoma (G-3610).

contain more carbonate, and are full of tiny inclusions. In the coned
zone the shale layers are thicker (0.02 to 0.6 mm.), more widely sep-
arated, and all inclined steeply in one direction relative to the shale
lenses of the interior zone, although across the whole width of the con-
cretion the partially conical layers have symmetrical arrangements
similar to that of specimen G-638. Between the shale layers are
crystalline carbonate conic scales. The shale layers bear the char-
acteristic "teeth" on the surfaces facing the center of the concretion.
From the "teeth" fine shale trails pass into the carbonate layers,
forming an acute angle with the shale layer and pointing away from
the interior of the specimen. The particles comprising the shale
have a high birefringence and are probably illite or sericite; they are
preferentially arranged parallel to the length of the shale lens. Some
of the lenses have an outer darker and denser band 0.016 to 0.024
mm. wide and more rarely an inner band 0.008 to 0.024 mm. thick.
Occasionally on the inner side of a shale lens there is a band of car-

WOODLAND: CONE-IN-CONE STRUCTURE 237

bonate 0.039 mm. wide that contains fewer inclusions than the nor-
mal carbonate. The carbonate conic scales are composed of "dirty"
grains, which have the typical spindle shape on extinction, 0.06 to
0.33 mm. long; the long dimension is oriented approximately parallel
to the shale trails described above. In places there are microcones,
0.19 mm. high, of fine shale layers with an apical angle of about 40°.
They are particularly well developed in the region where the shale
layers and conic scales are bent around to a small angle with the ex-
ternal surface of the concretion. The calcite spindles are oriented
parallel to the microcone axes and normal to the outer surface. Irreg-
ular opaque grains, up to 0.08 mm. in width and silvery gray in
reflected light, occur sparsely throughout the section but are more
common in the interior than in the coned layer.

16. Calcite Lenses, Big Pond Creek,
Parke County, Indiana (Slide Nos. 260-261)

Lensoid fillings of white calcite follow the outline of shells of
Dunbarella and bear the impression of the external ornament of the
shell. They occur in the Logan Quarry shale, Staunton formation.
Their thickness far exceeds that of the original shell; the maximum
thickness of the lens in the thin section is 2.61 mm. The calcite is
fibrous, with a central parting where there is evidence of crushing
into small grains. Cleavages are prominent at the distal ends of the
fibres and the length of the fibres is nearly parallel to the crystallo-
graphic "c" axis. Thin dense shale partings interrupt the fibres in
places and a parting is present in the calcite on each side of such
shale layers. There is no evidence of cone structure.

17. Calcite Vein, Trumpet Valley, Parke County, Indiana

A calcite vein (G-3564) from Logan Quarry shale, Staunton for-
mation, 10 mm. thick and unrelated to shells, has a similar struc-
ture to the above except that near one boundary there are lenses of
black shale inclusions that have the form of small arcs in section.
When a vertical polished surface through the vein is etched with
dilute hydrochloric acid, the shale lenses are seen to be saucer-shaped,
thus appearing as incipient cone forms. They originated obviously
from the disruption of shale laminae; their incorporation into the
growing calcite and their distortion are both due to growth of the
fibres.

238 FIELDIANA: GEOLOGY, VOLUME 13

18. Calcite Lens with Trilobite Elrathia kingii,
Deseret, Utah

Specimens of trilobites occurring as concretionary bodies in Mid-
dle Cambrian shale are well known and have been described by
Bright (1959) . They are remarkable in that they are relatively thick
objects. One example in the Museum's collection (PE-554) is over
8 mm. thick, and possesses a well-preserved form of the upper sur-
face of the carapace on one surface and a poorer form of the lower
surface of the carapace on the other. According to Bright (1959)
the majority of the specimens occur the right way up.

VERTICAL LONGITUDINAL SECTION DOWN THE AXIS OF THE
TRILOBITE (SLIDE NO. 263)

The maximum thickness of the specimen is 4.0 mm. and the cal-
cite fibres comprising it vary in length up to 2.32 mm. and up to
0.18 mm. in diameter. There is a considerable amount of dust in-
clusions and in part this is aggregated into cone-shaped lines that
point toward the dorsal surface (fig. 67) ; the cones also show up as
relatively dust-free areas in the more dusty surrounding calcite.
These cones normally extend throughout the thickness of the lens
but some of them terminate before reaching the dorsal surface. The
apical angles are about 26°.

Under crossed nicols the calcite fibres are seen to be arranged
generally with their length perpendicular to the dorsal-ventral sur-
faces, but in the cones there is a divergence that parallels the lines of
dust inclusions marking the cones (fig. 67, b) . In addition, the areas
between the apices of the cones are infilled with fibres arranged in
small bundles pointing toward the ventral surface (fig. 67, 6). The
dust inclusions appear to be present both as inter- and intra-granular
particles. In some areas there is a more than usual accumulation of
dust; the calcite in such areas is not fibrous but is highly irregular
(fig. 67). The crystallographic "c" axis of the calcite is essentially
parallel to the length of the fibres.

TRANSVERSE VERTICAL SECTIONS OF THE TRILOBITE
(SLIDE NO. 264)

Three sections taken across the cephalon and thorax show micro-
scopic structures similar to those in the longitudinal section. Some
idiomorphic pyrite occurs within the calcite without disturbance to
the fibres. In places the fibres are curved toward the dorsal surface,
particularly where there is a change in contour of the surface, e.g.,

c
o
w

'V to

03 ,

—. O

IS

P

B .
-■i

•a is
bt o

03 -o

'3'm

.a s
5 .a

t3 e

3 ..

.2 S
_ *-■

2«~

s

239

Fig. 68. Horizontal thin section through coned concretion that bears replica
of Elrathia kingii on dorsal and ventral surfaces, showing image of trilobite.
Deseret, Utah (slide no. 262).

240

WOODLAND: CONE-IN-CONE STRUCTURE

241

O-

V

op-

0.5mm
» 1

Fig. 69. Horizontal thin section showing enlarged view of part of axial region
of image shown in figure 68 (slide no. 262).

at the dorsal furrows, which mark the junction of the axis and the
pleura.

HORIZONTAL SECTION (SLIDE NO. 262)

A horizontal section was made approximately through the middle
of one calcite-thickened trilobite specimen. The astonishing result
is that an excellent image of a trilobite is preserved in the calcite;
the axis, segments, and glabella, for example, are clearly discernible
because of the dust accumulations (fig. 68). The calcite is fine-

242 FIELDIANA: GEOLOGY, VOLUME 13

grained (ca. 0.1 mm. across). The "c" axes of the grains are mainly
nearly perpendicular to the section. Along each side of the axis are
incomplete concentric arcs of dust (fig. 69) in a relatively dust-free
zone. Other poorly developed arcs of dust occur in the glabella re-
gion and in the relatively dust-free zones that alternate with dust-
rich zones in the pleural region. The dust-free zones appear to be
related to the relief of the original carapace, e.g., between the seg-
ments and at the dorsal furrows between the axis and pleura. The
dust is composed of minute wispy particles that are concentrated
into thin irregular aggregates in the arcs (fig. 69) ; some particles are
0.012 mm. across. The incomplete arcs result from the intersections
with cones, which are seen in the vertical sections. The dorsal sur-
face of most of the specimens available has a thin adhering shiny
black crust that can easily be flaked off the underlying calcite. In
one specimen it is largely calcareous, with some insoluble mineral
particles and brownish-colored aggregates; in another it is composed
of birefringent crystals up to 0.25 mm. across, insoluble in hydro-
chloric and hydrofluoric acids, with fine opaque matter and brownish
birefringent needles up to 0.2 mm. long. This thin layer may repre-
sent the mineralized carapace or perhaps only the upper layer of the
carapace. Bright (1959) says that the carapace is usually replaced
completely with cryptocrystalline calcite and rarely replaced by iron
oxide or silica. He considers that ". . . combination of the uneven
carapace and pressure was probably a factor in the development of
the cone-in-cone." He also suggests that ammonia produced by de-
cay of the soft parts of the trilobite was instrumental in the precipi-
tation of the carbonate and the development of the concretion.

The presence of an image of the fossil within the calcite vein is
highly revealing. The dust particles are presumably fine-grained
clay material that originally lay beneath the carapace. Growth of
the calcite fibres downward from the ventral surface of the carapace
has caused the loose clay particles to be dispersed in essentially a
vertical direction. Conical growth and displacement of the dust into
the conical surfaces have been concentrated along originally reflexed
or thickened portions of the carapace (e.g., at the apodemes, the
thickened ventral knobs for muscle attachment), with the develop-
ment of relatively dust-free zones and thus an outline of the form of
the carapace and production of the image.

Loose clay in the concavities of the ventral surface may have
been displaced downward, forming "dirty" zones, while opposite the
apodemes and reflexed zones there would have been fewer loose par-

WOODLAND: CONE-IN-CONE STRUCTURE 243

tides available and calcite growth would have been cleaner. The
restriction of the prominent coning to the reflexed and thickened
portions of the carapace suggests a physical control. Initiation of
the crystallization at these points and its conical increase downward
ahead of the crystallization below the concave portions would have
given rise to relatively dust-free conical zones. The replica of the
ventral surface on the lower surface of the concretion may have been
caused by the presence of a compacted impression in the clay layers
immediately beneath the carapace. The impression controlled the
thickness of the calcite and was pushed away from the carapace by
the downward growth.

19. Trilobite, Argentina (PE-6164)

MACROSCOPIC STRUCTURE

A large Thysanopyge argentina from the Middle Ordovician of
Argentina shows a structure similar to the above. Harrington and
Leanza (1957) describe the occurrence in Arenig shales of northern
Argentina of clay discs bearing crusts, 10 to 20 mm. thick, of cone-
in-cone in which the cones point to the interior. Cone-in-cone also
is present as laminae 20 to 30 mm. thick with the cones pointing
toward the center. Further, they say (p. 52) : "Many of these cone-
in-cone crusts contain beautifully preserved remains of complete
trilobites including huge specimens of Thysanopyge argentina up to
40 cm. in length. The blurred shape of the trilobite is always de-
tected on the outer surfaces of the cone-in-cone layers, and parting
the laminae along the mesial plane where the cone points end, excel-
lently preserved specimens are always found."

The trilobite specimen is about 225 mm. long and has a maximum
breadth of 177 mm.; it is 16 to 17 mm. thick. The sides have a
fibrous structure. A small vertical cut at the margin shows a cone
structure formed of brown layers in a dense hard brown matrix that
gives a slight effervescence in dilute acid when scratched. The ven-
tral surface, a replica of the ventral surface of the carapace, has a
number of cone cups, the bases of which are 6 to 7 mm. across.

MICROSCOPIC STRUCTURE

A thin section (slide no. 265) from the marginal area shows a
dense brown, very fine grained matrix with partially conical lines of
opaque blebs, which are red-brown in reflected light (?iron oxide-
stained). The matrix is peppered with minute grains (ca. 2 to 3 mi-

244 FIELDIANA: GEOLOGY, VOLUME 13

crons), which have a higher birefringence than the rest; the grains
appear to be of calcite set in silica. Throughout the slide there are
numerous small brownish aggregates about 0.015 mm. across, which
are made up of very minute particles; in addition, there are minute
flakes, presumably clay minerals or micas.

It is considered probable that the material between the dorsal
and ventral surfaces was originally composed entirely of calcite, the
growth of which occurred on the ventral surface of the carapace and
caused the cones. Subsequently, this calcite was largely replaced by
silica so that only minute blebs now remain, and the crystal structure
was destroyed. The fibrous nature is preserved on the marginal
surface, although no remnant of this is visible in thin section. The
cones, formed of the opaque materials, are also preserved in the re-
placing matrix.

20. Ptychoparid Trilobite in Calcite Concretion,
Gibson Lake, Teton County, Montana (G-3569)

Two specimens were kindly made available to me by Dr. A. R.
Palmer of the United States Geological Survey. They are from the
Middle Cambrian Switchback shale. These are relatively thick (one
13 mm.) concretions with a poor trilobite image on one surface and
a barely discernible image on the other. In vertical thin section
(slide no. 287) one concretion (9.3 mm. thick) is seen to be composed
of fibrous calcite. The replaced and fractured carapace, approxi-
mately in the center (fig. 70), is present as a cryptocrystalline calcite
layer 0.015 to 0.018 mm. thick with a discontinuous opaque layer
0.005 mm. thick; in part, however, it appears as a double layer
0.06 mm. thick with included opaque streaks. The fibrous calcite
of both the upper and lower layers of the concretion has a complex
series of cones formed from fine included material, presumably clay.
The cones, in contrast to those of the Elrathia specimen (fig. 67), are
of varying heights and their apices occur at different levels within
the layers. There are relatively dust-free, inwardly pointing, con-
ical areas in which the calcite is coarsely fibrous (up to 2.1 mm. thick)
and darker areas with considerable clay inclusions where the calcite
is more irregular. These "dirty" areas tend to have an outwardly
pointing conical form. There are some thicker lenses of clay, par-
ticularly in the ventral layer, and one bears a few corrugations on
the surface facing toward the trilobite. It is not easy to determine
the direction in which the cones point, because in each layer they
appear to be directed both toward the carapace and away from it.

WOODLAND: CONE-IN-CONE STRUCTURE

245

>tj

I.Omm

i 1

Fig. 70. Vertical transverse section of coned concretion with trilobite image
on dorsal and ventral surfaces; trilobite lies in median parting of concretion.
Gibson Lake, Teton County, Montana (slide no. 287).

However, in the ventral layer the true direction certainly seems to
be toward the fossil, while in the dorsal layer it also is probably
toward the trilobite.

There is no clear relationship of the clay-rich and clay-poor zones
to the contours of the carapace. However, the breaks in the latter
and the reflexed zone beneath dorsal furrows do influence the calcite
structure and the cone forms. The calcite commenced to crystallize
after the fracture of the carapace but while the enclosing clay was
still soft and unconsolidated.

21. Calcite Lens, Cedar Bluff, Alabama (G-3570)

Dr. A. R. Palmer of the United States Geological Survey has
kindly supplied a specimen of fibrous calcite from the Conasauga
shale (Cambrian). He informs me that trilobites occur on a thin

246 FIELDIANA: GEOLOGY, VOLUME 13

parting between two layers of fibrous calcite. The specimen consists
of one of these layers, some 17 to 18 mm. thick, together with the
fossil-bearing parting.

In thin section (slide no. 280) the calcite is coarsely fibrous with
fibres up to nearly 10 mm. in length but only up to about 0.28 mm.
in width. There are numerous fine inclusions mainly disposed in
streaks parallel to the fibres, but toward the parting there are very
acute conical forms in the dust directed toward the parting. The
shape of the calcite fibres is here related to the cone forms. Near
the parting there are some small clay lenses, one of which has a par-
tially conical form with corrugations on the surface facing the parting
toward which the apex points.

22. Concretion with Trilobites, Cabrieres, Herault, France

(P-196, P-200)

MACROSCOPIC DESCRIPTION

These specimens, up to 29 mm. thick, are parts of siliceous con-
cretions of Ordovician age. They bear on one surface fragments of
replaced dorsal tests of asaphid trilobites. The other surface is
rounded and has concentric markings that are the bases of cones, as
well as some corrugated cone cups up to 10 mm. in diameter. Pol-
ished vertical surfaces exhibit many buff-colored partially conical
shale laminae, some of which bear the stepped or corrugated struc-
ture on the outer surface. The cone apices point toward the trilo-
bite-bearing surface; near the surface the conical layers are more
numerous but less regularly formed. The matrix is dense, fine-
grained silica similar to that of the Argentine trilobite (PE-6164)
and the siliceous concretion (G-638). These concretions have been
described in detail by Cayeux (1935), Bonte (1945a), Thoral (1946),
and Denaeyer (1947). Bonte reports that the nodules, called "ga-
teaux," occur generally as very flattened ellipsoids and frequently
contain in the equatorial plane entire or fragmentary fossils, mainly
trilobites. The shape of the "gateaux" is governed by the shape of
the fossils they contain and the cones of the two halves point toward
the center of the nodules. Bonte also shows that the position of the
conspicuous cone bases, called "mamelons," on the nodule surfaces
is influenced by the relief of the trilobite carapace.

MICROSCOPIC STRUCTURE (SLIDE NO. 621)

In thin section the partially conical shale layers are seen to occur
in a very fine grained chert-like matrix composed mainly of quartz

WOODLAND: CONE-IN-CONE STRUCTURE

247

0.5 mm

Fig. 71. Vertical thin section of calcite vein in calcareous siltstone.
Point, Quebec (slide no. 269).

Fleurant

or chalcedony grains about 3 to 15 microns in diameter. The matrix
grains are stained, presumably by iron oxides. Tiny micaceous grains
and opaque specks also occur among the silica. In places there is
micaceous material in very thin lines that suggest weakly developed
microcones, the "structure entrecroisee" of Bonte (1945a).

It is considered that, like the other siliceous specimens, these from
HeYault represent silica replacement of originally calcareous concre-
tions. The macrocones are preserved as well as a trace of the micro-
cones, but the characteristic microstructure of typical cone-in-cone
has been destroyed by the replacement of the calcite by silica.

23. Calcite Veins, Escuminac Formation (Late Devonian),
Fleurant Point, Quebec (G-3562-64; Slide Nos. 268-269)

Calcite veins 0.14 to 3.0 mm. thick occur intercalated with thin
greenish-gray shale (up to 0.05 mm. thick) and calcareous silty shale

248

FIELDIANA: GEOLOGY, VOLUME 13

(up to 0.12 mm. thick). The specimens were collected by Dr. R.
Denison for the Bothriolepis specimens they contain.

Fig. 72. Vertical thin section of double calcite vein in calcareous siltstone.
Fleurant Point, Quebec (slide no. 269).

The calcite is fibrous, with its long direction perpendicular to the
contacts; the "c" axes of the grains lie parallel to the long direction
or nearly so (grains often extinguish at a small angle to the length) .
The fibres are up to 0.7 mm. across and may extend nearly the full
thickness of the vein. The thicker veins have a distinct comb struc-
ture and the calcite grains, although their long directions are par-
allel, are angular in shape and termination (figs. 71 and 72). Many
of the grains have twin lamellae in one or two directions. Both
margins have fine-grained calcite although it is more prevalent at
one margin, possibly the lower one, based on the orientation of a fos-
sil fish contained in the specimen. A conical structure formed by
lines of minute inclusions is present (fig. 71) ; these lines of inclusions
are inter- and intra-granular and may run the entire thickness of the
vein. The cones appear to point mainly in one direction ^down-
ward) but the structure is not always clear and some cones may
have the reverse orientation.

WOODLAND: CONE-IN-CONE STRUCTURE

249

A double vein (fig. 72) has an upper (?) layer of needle calcite
1.25 mm. thick and an intermediate zone, about 0.42 mm. thick, of
small grains of calcite with much fine dust, which merges into a

:**9#

-

0.5mm

Fig. 73. Vertical thin section of calcite lens in calcareous siltstone.
Point, Quebec (slide no. 268).

Fleurant

lower(?) zone of needle calcite 0.74 mm. thick. Conical lines are read-
ily discernible, particularly in the lower(?) zone, where they appear to
point mainly upward, although it is difficult to be sure of their true
orientation. The lower (?) border of the central dusty zone has conical
projections of dust aggregations directed mainly downward. The
dust cones are partly related to the shape of the calcite grains. The
cones of the upper(?) zone are poorly developed but seem to point
mainly upward as in the case of the lower (?) zone. Well-developed
stylolite sutures cross the veins at intervals running in a more or less
vertical direction (figs. 71 and 72). Thinner veins of calcite are often
lens-like (fig. 73), associated with a thin clay lens either above or be-
low the vein. In some cases a clay layer has been disrupted by calcite
growth at places above the clay layer and in adjacent areas below it;
the opposite direction of calcite growth has broken up the clay layer

250

FIELDIANA: GEOLOGY, VOLUME 13

0.2 mm
i i

Fig. 74. Vertical thin section of calcite veins and clay laminae in calcareous
siltstone. Fleurant Point, Quebec (slide no. 269).

and moved the parts differentially upward or downward (fig. 74).
If the clay lens lies below the calcite, the latter has cone forms point-
ing upward, and the reverse is true in cases where the clay lies above.
The calcite immediately adjacent to the clay layer appears less
charged with dust and thus seems to be the latest part added. In
cases where calcite has crystallized on both sides of a clay lens the
cones appear to point away from each other.

The calcite veins formed after deposition but probably early in
the diagenesis before there had been much induration of the sedi-
ment, so that some of the sediment could be incorporated and dis-
tributed as individual particles in the growing calcite. The cone
forms are a direct result of the growth of the calcite and are not
related to the twin lamellae or the stylolites, both of which cut the
cone structure and were probably caused by the Shickshokian (Aca-
dian) deformation that affected the region (Alcock, 1935). The

WOODLAND: CONE-IN-CONE STRUCTURE 251

carbonate of the veins possibly resulted from the redistribution of
the calcite in the sediment.

24. Coned Calcite Veins in Black Shale,
Cunningham Brook, New Brunswick (G-3640-42)

These specimens were collected by Dr. R. Denison for the fossil
fish remains they contain. The shales belong to the Jones Creek
formation of Silurian age.

MACROSCOPIC STRUCTURE

The concretions are contained in a dense, finely laminated black
shale. There are two types: (1) a fine-grained, dense, homogeneous,
calcareous clays tone type, which may contain a layer of fish scales;
and (2) a coarse-grained, relatively pure calcite with wisps and lami-
nae of shale. The latter type is more irregularly developed than the
former and has the appearance of vein calcite except for the irregular
shape of the masses. A layer of fish scales is present in one example.
Cone forms are visible in the second type, which apparently often,
but not invariably, occurs in close juxtaposition with the fine-grained
homogeneous type. The structure of these coned calcite masses can
best be investigated in thin section, although the conical clay layers
and undulating clay and silt layers that can be traced from the shale
into the veins are clearly seen on polished vertical surfaces under the
binocular, particularly if etched with dilute acid.

MICROSCOPIC STRUCTURE (SLIDE NOS. 281-282, 288-289)

The shale is composed of light buff -colored, homogeneous clay
layers up to about 2 mm. thick, and thinner, dark brown, more irreg-
ular clay layers up to about 0.25 mm. thick, alternating with calcare-
ous silty layers up to about 0.5 mm. thick. The calcite veins vary in
thickness, the thickest in the collection being 20 mm. Some veins
are evenly developed and parallel to the bedding but most of them
are more irregular in shape and terminate laterally at an abrupt high
angle against the shale; occasionally they are notably rounded, bulb-
ous, or saucer-shaped (fig. 75). The veins contain bands of shale
and silt that are deformed into open folds and into conical forms
(figs. 75-77). The conical forms have well-defined corrugations on
the outer surface. These bands can be traced across the vein into
the shale and clearly indicate the expansion of the shale caused by
development of the calcite (fig. 75). Pyrite is of common occurrence

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WOODLAND: CONE-IN-CONE STRUCTURE

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Fig. 76. Vertical thin section of coned calcite veins showing variable position
of a vein with respect to a clay lamina shown at top of photograph. Cunningham
Brook, New Brunswick (slide no. 288).

in the shale, in the vein calcite, and in the shale and silt bands within
the veins. Throughout the veins there are many inclusions, frequently
in fine lines and cones, that are both inter- and intra-granular. The
calcite is usually coarse-grained, up to about 4 mm. long and 0.37 mm.
wide; the long dimensions are generally more or less vertical and the
grains do not extend the full height of the vein. Many do not extin-
guish between nicols parallel to their length. In places the calcite
fibres are gently inclined to the horizontal, more or less parallel to
clay layers. The calcite grains have irregular shapes, often wedge-
or spindle-shaped, presumably caused by crowding. Some of the
veins have a considerable clay content which "chokes" the calcite;
the latter is consequently much more irregular and finer-grained,
about 0.04 to 0.06 mm. across. The clay in such veins is present as
spongy aggregates rather than well-defined layers, but partially con-

254

FIELDIANA: GEOLOGY, VOLUME 13

0.5mm

Fig. 77. Vertical thin section of coned calcite veins showing clay arcs derived
from a clay lamina within which a calcite vein had formed; opaque areas are py-
rite. Cunningham Brook, New Brunswick (slide no. 288).

ical forms can be discerned (fig. 78). The locus of development of
the calcite may vary within a clay layer so that at one point a thicker
amount of clay lies above the vein than below but this passes to a
zone showing the reverse situation (fig. 76). One particular vein has
in part a central line which appears to be a zone of very fine calcite
and clay which extinguishes parallel to its long direction; it passes
along the vein to a position near one bounding surface, apparently
indicating a difference in the relative amount and direction of growth
of the calcite fibres (fig. 77). Micro-shears disrupt this central line
in places with thrust-like displacements, the vertical movements on
which range from 0.05 to 0.14 mm. Twin lamellae in one or two
directions occur in many of the calcite grains. One specimen (slide
no. 289) has a layer of fish scales and interstitial calcite occurring
within the coarse fibrous calcite of a vein. In another (slide no. 281)
a layer of fish scales with calcite between the individual scales occurs

WOODLAND: CONE-IN-CONE STRUCTURE

255

2 mm

i 1

Fig. 78. Vertical polished and etched surface of calcite veins showing delicate
clay films with conical form. Cunningham Brook, New Brunswick (G-3641).

in a fine-grained, homogeneous, calcareous mudstone that appears to
have been thickened by concretionary addition of the calcite (fig. 79).
A silty layer, 1.07 mm. thick within this concretion, can be traced
into a coarse calcite vein (fig. 79) ; the calcite above and below this
layer contains clay cones that point toward the layer. One border
is the boundary of the vein but the other is an undulating and coned
shale layer within the vein. The former border is a plane surface
except for a series of cones that disrupt the bounding clay, which
rises in a series of small corrugated cones into the vein.

It is difficult to determine the absolute movement of the clay
bands in the veins, although the relative movement is obvious. If
trails of clay which rise from the corrugations of many of the clay
bands (figs. 80, 81) indicate the direction of movement, then this
movement is toward the bases of the cones and thus the same as the
probable direction of growth of the calcite grains. The outer sur-
face of the partially conical clay layers is consistently the one that
is corrugated (figs. 75, 81). The origin of this corrugation suggests
a direct relationship to the mode of origin of the conical clay bands.

256

FIELDIANA: GEOLOGY, VOLUME 13

, / mm ,

Fig. 79. Vertical thin section of double-coned calcite vein with silt parting
and showing part of layer of fish scales enclosed in fine-grained structureless car-
bonate concretion. Cunningham Brook, New Brunswick (slide no. 281).

The corrugations are on the side from which the clay bands have
been moved and disrupted by the growth of the calcite. The inner
surface of the conical clay layer always appears as a smooth line in
the sections. It presumably represents the originally horizontal clay
surface, on or under which calcite was crystallizing simultaneously
with the growth on other surfaces that resulted in the displacement
of the layer.

The clay structures in the calcite veins are vividly displayed when
a polished surface cut perpendicular to the bedding is etched with
dilute hydrochloric acid. The calcite is removed and the remaining
insoluble matter largely retains its original orientations. The par-
tial cones with their corrugations are visible as exceedingly fine films
(fig. 78). I am grateful to Dr. E. Olsen for an X-ray analysis of one
of these films, which indicates the presence of illite, quartz, sericite,
and carbon. This is consistent with its origin as a clay probably

WOODLAND: CONE-IN-CONE- STRUCTURE

257

0.2 mm

Fig. 80. Vertical thin section of calcite vein with corrugated clay layers (ver-
tical) derived from clay lamina. Cunningham Brook, New Brunswick (slide
no. 282).

deposited in a marine environment. Some of the veins after etching
show such a considerable quantity of inclusions that a dense gray
mass remains. This, however, has a very light and porous tex-
ture, resulting from the expansion of the original clay produced by
the growth of the fine-grained concretionary calcite; partial cone
forms can be discerned but they are not so well developed as in the
coarser veins.

The twin lamellae and micro-shears do not appear to be related
in any way to the development of the veins or to the conical clay
layers. They are probably later structures, formed during the Aca-
dian orogeny that affected the rocks of this area (MacKenzie, 1951).

25. Calcite Veins, One Mile Northwest of Myton,
Duchesne County, Utah (G-3694)

These specimens were collected by Dr. John Clark from the up-
per part of the Myton member (Uinta C), Uinta formation, of Late

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WOODLAND: CONE-IN-CONE STRUCTURE 259

Eocene age. The veins occur parallel to the stratification in thinly
bedded, greenish-gray, sandy siltstones that contain abundant car-
bonized plant remains and gypsum laminae. Dr. Clark interprets the
beds as non-marine near-shore deposits of a lacustrine environment.

MACROSCOPIC STRUCTURE

One specimen of a vein is divided into two layers, 5.5 and 13.5
mm. thick, of pure, white, fibrous calcite. A vertical fracture surface
exhibits finely corrugated partial cone-cups, the apices of which point
toward the interior of the vein.

MICROSCOPIC STRUCTURE (SLIDE NO. 824)

The calcite fibres are from about 0.09 mm. to, rarely, 0.42 mm.
across and up to 2.3 mm. long. The junction of the two layers is
marked by a zone, 0.1 to 0.2 mm. wide, of fine-grained calcite. Inter-
calated inter-granularly and perhaps, in part, intra-granularly are
clay films 0.028 mm. to 0.038 mm. thick that transgress the general
trend of the fibres to form acutely pointed cones. The apices are
formed mainly at the wedge-shaped terminations of the fibres. An
occasional clay layer has a step-like form.

These veins thus show an incipient cone structure that is better
developed than in the veins from Fleurant Point, Quebec, is quite
similar to the lens from Cedar Bluff, Alabama, but is not so well
developed as in the veins from Cunningham Brook, New Brunswick.

26. Tracy, Iowa (G-3561)

These specimens were collected from a spoil heap of a surface
working of Pennsylvanian coal and were donated to the Museum by
Mr. J. Wollin, who reports that they occur as concretions.

MACROSCOPIC STRUCTURE

The maximum thickness is 205 mm. Fibrous structure is very
evident and relatively pure calcite needles are readily seen under
30 X magnification. Cones are poorly formed and packed so closely
together that they interfere with one another. Individual partial
cones attain a height of about 68.3 mm. but are often smaller; some
are curved and the calcite needles are also curved. Shaly lenses are
irregular; some are thin and lie between the calcitic cones, and others
occur as horizontal wedges. The cone angle is generally very acute

260 FIELDIANA: GEOLOGY, VOLUME 13

and varies from 14° in small cones to 50° in larger ones, averaging per-
haps between 20° and 25°. Inner cone-cup surfaces are very corru-

Fig. 82. Vertical thin section of cone-in-cone specimen. Tracy, Iowa (slide
no. 258).

gated and the vertical step portion is up to 2.76 mm. in depth. The
steps of the corrugations are clearly composed of fibrous calcite. In
some parts of the specimens the calcite is not fibrous but apparently
structureless, with penetrations of thin "curtains" of inclined fibrous
calcite.

MICROSCOPIC STRUCTURE

Vertical section (slide no. 258). — The vertical calcite fibres are
large, up to 2.8 mm. long and about 0.09 to 0.20 mm. wide, although
between crossed nicols they appear as aggregates of narrower par-
allel fibres. Conical lines are formed by clay inclusions within and
between the fibres (fig. 82) . The calcite within the cones extinguishes
parallel to the cone walls so that the conical structure seems to be
controlled by the crystallization of the calcite fibres. Cleavages are
prominent in some of the fibres and bear no relationship to the cones.

WOODLAND: CONE-IN-CONE STRUCTURE 261

In places there are denser patches of clay inclusions where the calcite
is more irregular and finer in grain.

Horizontal section (slide no. 255). — The clay is aggregated into
many incomplete interfering arcs up to about 0.12 mm. across. Py-
rite and fossil fragments occur sparsely. The calcite grains vary
from about 0.015 to 0.06 mm. in diameter.

27. Kentucky (G-1357)

No information on the locality or stratigraphical occurrence is
available for this specimen.

MACROSCOPIC STRUCTURE

The cones are extremely well developed and individualized, and
they extend throughout the whole thickness (22.52 mm.) of the layer.
Between the cones are partial cones of fibrous calcite but in some
cases the material appears to be a structureless calcilutite. The cone
surfaces have both longitudinal and concentric striations. The
cones flare out at the base so that the cone angle varies from about
24° at the top to 40° about a third of the way down and 76° near
the base. Some cones extend upward from the base for 12.22 mm.,
at which point there is a suggestion of a horizontal parting.

MICROSCOPIC STRUCTURE

Vertical section (slide no. 271). — The calcite appears to be very
fine grained (0.02 mm.) but between crossed nicols spindle-shaped
areas extinguish as units up to ca. 1.85 mm. long, possibly because
incipient recrystallization tends to form larger individuals. The
spindles are more or less parallel to the cone axes but they do not
extinguish together. There are considerable inclusions of clay par-
ticles and these are, in part, aggregated into indistinct conical lines.
Toward the base of the cones there are numerous faint bands similar
to those previously described in the Dotson's Branch specimen
(p. 207). One corrugated clay layer, 0.04 to 0.16 mm. thick, occurs
within the cone and is parallel to one side of it.

Horizontal section (slide no. 270) . — This shows a dense meshwork
of incomplete clay arcs 0.03 to 0.04 mm. across. The calcite is fine-
grained (up to 0.03 mm.) but aggregated into irregular patches up
to about 0.28 mm. across, which almost extinguish as a unit between
crossed nicols. This patchy extinction may be the result of incipient
recrystallization.

262 FIELDIANA: GEOLOGY, VOLUME 13

28. Ohio Shale (Devonian), Cooper's Hollow, Ohio

(G-3607)

These specimens were collected and donated to the Museum by-
Miss Carole Stentz. They occur in the Upper Devonian Ohio shale.
One specimen is described both macroscopically and microscopically.

MACROSCOPIC STRUCTURE

The specimen is about 36 mm. thick with the weathered vertical
surface showing partially cone-shaped lines, some of which are ar-
ranged in a cone within a cone series, pointing toward the upper
surface. A freshly broken vertical surface bears both cone and cone-
cup surfaces. The cone surfaces are formed of partially conic scales
and bear longitudinal striations as well as — to a lesser degree — in-
complete horizontal concentric ribs. The cone-cup surfaces have the
characteristic corrugated or step-like structure formed by clay layers
and lenses. The cone angle is small (about 20-25°) but flares toward
the base. The bottom surface of the specimen has incomplete arcs
marking the intersections of partially conical clay surfaces. These
are commonly arranged in more or less complete concentric circles
outlining the bases of macroscopic cones up to 19 mm. across. As
the fine-grained gray carbonate is homogeneous and shows no fibrous
structure, the cone surfaces have the appearance of being superim-
posed on a structureless matrix.

MICROSCOPIC STRUCTURE, VERTICAL SECTION (SLIDE NO. 294)

The clay layers of the macrocones are from about 0.016 mm. to
0.12 mm. thick. In most cases the clay is diffuse and intermixed
with calcite and not so well defined as in most other specimens. The
corrugated surface is also not well marked except in a few of the
layers. Microcones of very fine clay layers occur throughout, the
individual cones ranging from about 0.2 to 1 mm. in height. The
calcite is fibrous, with fibres up to about 1.4 mm. long by 0.1 mm.
broad, in the uppermost portion of the specimen. The calcite passes
downward into more spindle- or fan-shaped grains, which are about
0.23 to 0.32 mm. long and 0.02 mm. to 0.06 mm. broad near the base.
The fibres and spindles are oriented with their length normal to the
top and bottom surfaces of the coned layer; their shape and orienta-
tion are related to both the micro- and macrocones. The clay par-
ticles of the microcones appear to be present within as well as between
the grains. Throughout the slide are scattered many minute (0.004

WOODLAND: CONE-IN-CONE STRUCTURE 263

to 0.007 mm.) granules and cubes of pyrite. These are more numer-
ous in some zones and especially in some of the thicker clay layers.
The microscopic structure is thus similar to that of all cone-in-
cone specimens and proves that the macrocones are related to the
microcones and to the calcite fabric throughout the matrix and are
not merely superimposed structures.

29. Cone-in-Cone, North of Greybull, T53N, R94W,
Wyoming (G-3572-74)

Three specimens collected from the Upper Cretaceous and given
to the Museum by Mr. Neal Brown contain cone-in-cone calcite
layers associated with sandstone. The top of only one specimen
was identified.

MACROSCOPIC STRUCTURE

In one specimen (G-3572) the cone-in-cone layer is approximately
20 mm. thick and is composed of brown fibrous calcite; corrugated
cone-cup surfaces are developed and to a lesser degree cone surfaces
are visible. In many places individual partial cones extend the full
thickness of the layer. Coarse friable calcareous sandstone lies on
the apical surface of the cone layer. The oriented specimen (G-3573)
has a basal layer of cone-in-cone approximately 10 mm. thick, sep-
arated by about 45 mm. of coarse friable calcareous sandstone from
a thin fibrous calcite layer 3 to 6 mm. thick, similar to the lower layer.
The third specimen (G-3574) has a more irregular development of
brown fibrous calcite up to about 10 mm. thick on one surface.
Some small ellipsoidal masses a few millimeters long, of fibrous cal-
cite, are present in the calcareous sandstone immediately adjacent
to the fibrous calcite layer.

MICROSCOPIC STRUCTURE, VERTICAL SECTIONS

G-3572 (slide no. 284). — This specimen, which contains relatively
well-developed macrocones with corrugated cone cups, has coarse
fibrous calcite up to 2.9 mm. long by 0.14 mm. in diameter. Cone
surfaces of clay inclusions are well developed; the terminations of
the fibres and the shape of the calcite aggregates also form the cones.
The thicker conical clay layers are corrugated. Twin lamellae, ori-
ented in one or two directions, occur sparsely but bear no relation-
ship to the cones. Some grains of quartz and plagioclase occur among
the calcite and, rarely, have a clay concentration shaped like a dunce's
cap on the side facing the bases of the cones (fig. 83).

264

FIELDIANA: GEOLOGY, VOLUME 13

Fig. 83. Vertical thin section of coned calcite veins in sandstone showing
quartz grains and associated clay "caps." Near Greybull, Wyoming (slide no. 284)

G-3573 (slide no. 285). — Microcones pointing upward are only
rarely discernible in the fibrous calcite, and the clay inclusions are
mainly in the form of inter- and intra-granular streaks. The upper
surface of the vein is in contact with sandstone, which has consider-
able granular calcite cement. The contact is sharp and there is no
fibrous calcite in the sandstone, although there are some sand grains
dispersed in the fibrous calcite, particularly near the junction. Some
of the calcite — both the interstitial calcite of the sandstone and the
fibrous calcite of the vein — has twin lamellae.

G-3574. (slide no. 283). — Like the above specimen the sandstone
contains considerable granular calcite cement. Fibrous vein calcite
occurs along one margin and, although the actual contact is sharp,
there are lenses of vein material 4 to 5 mm. thick in the sandstone
near the more continuous vein. The fibrous calcite of the lenses has

WOODLAND: CONE-IN-CONE STRUCTURE 265

cones of clay inclusions and a few sand grains. The contacts of the
lenses with the sandstone are sharp.

It is considered that the coned fibrous calcite of these three speci-
mens crystallized in thin laminae or lenses of clay intercalated among
the sand. The latter is not involved in the calcite vein except for a
very small number of dispersed grains. These grains were caught
up passively in the growing calcite. The fact that some loose grains
were available suggests that the veins developed pari passu with the
cementation of the sand.

30. Needles Peak, Big Bend Region, Texas (G-3609)

This specimen was kindly supplied by Mrs. June Zeitner of
Mission, South Dakota.

MACROSCOPIC STRUCTURE

This specimen is composed of cream-colored, coarse, fibrous cal-
cite; macroscopic clay lenses are absent. Corrugated partial cone-
cup surfaces are well developed in one vertical fracture surface and
some poor partial cones are present on another. The coned calcite
is about 25 mm. thick but on one surface is a layer, about 3 mm.
thick, of coarse calcite fibres oriented normal to the fibers of the
main portion. The fibers of the thin layer have a radial arrangement
and in places they bend at a right angle and pass continuously into
the fibres of the coned portion.

MICROSCOPIC STRUCTURE

In thin section (slide no. 286) the main coned layer of the specimen
is seen to be composed of long calcite fibres up to about 0.23 mm. in
diameter. The fibres do not extend the entire thickness of the layer.
Fine clay inclusions form dense lines that essentially parallel the fibres
but have very acute conical forms. The thin layer (3.25 mm.) is made
up of calcite fibres up to 0.42 mm. in diameter and at least 9 mm.
long, oriented nearly at right angles to the fibres of the rest of the
specimen. Lines of fine, mainly intergranular, clay inclusions parallel
the fibres and possess only a slight suggestion of very acute conical
form. At some points along the contact between the two layers the
fibres of one bend continuously into parallelism with the fibres of the
other, whereas at other places the contact is discordant and sharp.
There is a little increase in the amount of included clay along the dis-

266 FIELDIANA: GEOLOGY, VOLUME 13

cordant contact. Neither the direction of growth of the fibres nor
the cause of the change in direction of their growth is known. That
it is a growth phenomenon is supported by the absence of twinning
and granulation along the contact, even in the fibres which can be
traced from one layer into the other.

31. Pottery Hill, Ottawa, Illinois (G-1824)

MACROSCOPIC STRUCTURE

The maximum thickness (33.60 mm.) of this Pennsylvanian speci-
men is the total of a number of layers varying in thickness from
2.00 mm. to 7.9 mm. The cones are very irregular and distorted and
pass into corrugated surfaces lacking a cone form, similar to those in
specimen G-3843, described above (p. 213). Fibrous structure is
plainly to be seen, especially on weathered surfaces. The fibres ap-
pear to be vertical to bedding even in coned portions. Horizontal
partings are very irregular and contain thin layers of micaceous clay;
on the better defined coned forms the surfaces are corrugated. Cone
cups are variable in size; one is about 13 mm. deep with vertical cor-
rugations about 0.5 mm. high and a "tread" that is inclined toward
the axis (cone apex down) . The total impression of the specimen is
that each layer has been pressed down into the one beneath with a
smear of clay between.

MICROSCOPIC STRUCTURE (G-1822)

Vertical section (slide no. 259). — This section is of interest because
it shows features intermediate between those of the coned calcite vein
from Cunningham Brook and the Woodland Valley and Dotson's
Branch specimens. There are several distinct coned layers separated
by non-coned layers (fig. 84). The coned layers are composed of typi-
cal spindle-shaped calcite and contain both microcones of clay and
well-developed, thicker, conical, corrugated clay lenses that tend to
be continuous across the slide. Two such layers are separated by a
wavy clay layer 0.23 mm. thick; the cones on each side of this clay
point in the same direction. The clay is believed to represent an
original layer that has been deformed and separated from other clay
layers by the growth of calcite and is thus similar in origin to the clay
and silt layers included within the calcite veins of the Jones Creek
formation described above (p. 251) . Although solution of calcite might
have been responsible for the origin of the clay, there is no evidence
for this; the clay is probably an original layer.

WOODLAND: CONE-IN-CONE STRUCTURE 267

One other separating layer, 0.9 mm. thick, is composed of fine-
grained calcite (0.005-0.015 mm.), clay, and pyrite particles. The
cones on either side point toward the layer and the junctions between

Fig. 84. Vertical thin section of cone-in-cone layers. Ottawa, Illinois (slide
no. 259).

the coned and non-coned sections are gradational. The relationships
are thus identical to those described for specimen G-3568 (p. 221)
and concretion G-151 (p. 224).

32. Pottery Hill, Ottawa, Illinois (G-1826A)

MACROSCOPIC STRUCTURE

This specimen has two distinct layers, a laminated dark gray
calcareous shale about 30 mm. thick and a buff crystalline carbonate
layer about 80 mm. thick. The sharp contact is generally a slightly
undulating plane presumably parallel to the original bedding. In
places, however, it abruptly steepens to a near vertical position for
some 10 or more millimeters before resuming its more normal, nearly
horizontal course. Under the binocular microscope the contact is
seen to be minutely irregular.

The carbonate layer appears to be coarsely fibrous and to have a
cone-in-cone structure; the cones and conic scales have a very acute
apical angle. Cone cups with corrugated surface occur rarely. The
shale layer is dense but exhibits a fine parallel banding, with laminae
from a fraction of a millimeter to 3 millimeters thick. Irregularly

268 FIELDIANA: GEOLOGY, VOLUME 13

shaped dark zones of material connected to the shale layer penetrate
and anastomose into the coned carbonate layer.

Etching with dilute acid emphasizes the structures. The bands
of the shale layer stand out as alternating laminae of greater and lesser
carbonate content. The laminae richer in carbonate have an incipient
microcone structure and also possess small lenses of compact clay.
The laminae terminate at an oblique boundary between the shale
and carbonate layers, although they are bent into partial conform-
ity. The carbonate layer shows considerable clay inclusions disposed
in innumerable, very fine, acutely conical planes. An occasional cor-
rugated conical layer, the apex of which points toward the shale
layer, is present. Some clay lenses several millimeters long interrupt
the conical structure.

MICROSCOPIC STRUCTURE (SLIDE NOS. 563-565)

The carbonate layer is dense with fine clay inclusions; at the
thin edges of the section the carbonate is seen to have a very fine
grained (mainly up to about 0.06 mm.) fibrous texture but it extin-
guishes as units over larger zones. Clay lenses up to 2.3 mm. long
and 0.23 mm. thick are present. On their upper and lower surfaces
they have fibrous calcite fringes up to 0.33 mm. thick, which are less
dense with inclusions than the surrounding carbonate. The irregu-
lar zones that are in contact with the shale layer are darkened by
much intergranular clay, and the carbonate grains (ca. 0.04 mm.
across) are equigranular instead of being fibrous.

The shale layer is very fine grained and made up of thin laminae
of different compositions. Bands of relatively pure, fibrous calcite,
0.23 mm. thick, occur among clay-rich bands. Some of the latter
have dense, saucer-shaped, clay lenses, each of which has fringes of
fibrous calcite. A microcone structure is discernible in some of these
fringes. Other bands are more homogeneous, but interstitial calcite
and small wisps of dense clay, 0.028 to 0.1 mm. thick, are present.
Lenses of coned fibrous calcite, 3 to 4 mm. thick, are inserted be-
tween the bands in places. Finely divided pyrite is disseminated
throughout the shale and also occurs in sparse aggregations.

The shale layer appears in many respects to be similar to the in-
terior portion of the coned concretion G-151 (p. 222), and the car-
bonate layer apparently is similar to the coned external layers. The
contact of the two layers is, however, much sharper than in the
concretion. Presumably the conditions of carbonate crystallization
changed abruptly. The boundaries between the coned carbonate

WOODLAND: CONE-IN-CONE STRUCTURE 269

and shale layer that are oblique to the presumed bedding are analo-
gous to those oblique boundaries in the coned veins from Cunning-
ham Brook (fig. 75).

33. Jubilee Creek, Peoria County, Illinois (G-2065)

The total thickness of the specimen is some 135 mm., but cone-in-
cone is restricted to about 105 mm. The cones are not well formed
but they show both external cone and internal cup surfaces. The
cone surfaces are strongly corrugated (vertical portions up to 2.42
mm. and shorter, slightly inclined portions ca. 1 mm.). The cup
surfaces are coated by a buff residue in some cases and by a gray-
green clay in others. The coned portion, which has a fibrous struc-
ture, passes into a greenish-gray calcareous layer that appears, in
part, to be recrystallized calcite with lenses of gray clay. The cone
angle is near 32° with a slight flaring toward the base.

34. Specimen of Unknown Origin (G-3593)

The total thickness of the specimen is about 150 mm. The cones
and cups are very well developed but interfere greatly with one an-
other. Cone-in-cone developed along a common axis is particularly
well seen (fig. 85). Clay lenses between conic scales are prominent
and the cone cups have a marked corrugation. The cones all point
toward one surface that has a few scattered fossils similar to the
Woodland Valley and Dotson's Branch occurrences. Fibrous struc-
ture is evident. A remarkable feature is the development of certain
"master" cone surfaces with clay layers that cut across other cone
surfaces.

35. South of Lovell, Wyoming (G-3578-84)

This material was collected from the Thermopolis shale, Upper
Cretaceous, by Dr. E. S. Richardson, Jr., and myself at a locality
found by Mr. Neal Brown. The cone-in-cone layers were exposed
by digging into weathered shale that dips 30°. It was not possible
to obtain unweathered material; much gypsum and limonite were
associated with the shale. The lower cone-in-cone layer is about
230 mm. thick, with gray shale below and a hard band, 140 mm.
thick, above, with gypsum seams and limonite. The upper cone-in-
cone layer, a lens-shaped body some 450 mm. across, is broken into
two parts, a lower one 45 mm. thick and an upper one 0 to 90 mm.

20 mm

i 1

Fig. 85. Large cone-in-cone specimen showing "nested" cones. Locality
unknown (G-3593).

270

WOODLAND: CONE-IN-CONE STRUCTURE 271

thick. The lower cone-in-cone layer fractures easily along vertical
surfaces. Acute cones point upward and coarse clay corrugations
are present on the cone cups. The ferruginous calcite has a fine
fibrous structure on weathered surfaces but otherwise appears dense
and dark brown in color. The upper cone-in-cone layers are similar
to the lower one but thinner, and the cones point downward. In
part the cone structure is not evident macroscopically. The tend-
ency for vertical fracture of the cone-in-cone layers produces many
pointed splinters that can commonly be seen lying in patches along
the strike of the weathered shale outcrop. The patchy occurrence
represents the frequency of the lenses characterizing certain strati-
graphic horizons.

The arrangement of the cones in the upper and lower layers is
identical to that of the cones in the concretion specimens at Elk
Creek (p. 225).

36. Fairburn, South Dakota (G-3588-92)

From the Sharon Springs member, Pierre shale, Upper Creta-
ceous, Dr. E. S. Richardson, Jr., collected specimens of cone-in-cone
lenses which laterally appear to be replaced by dense carbonate con-
cretions without cones at the same level. One specimen (G-3588) is
of typical complex cone-in-cone some 80 mm. thick and composed of
fine fibrous calcite. The partial cones point upward, but are not well
individualized as they greatly interfere with one another.

37. Concretions, Near Myton, Duchesne County, Utah

(G-3844-47)

A number of concretions were collected by Dr. John Clark from
the upper part of the Myton member (Uinta C), Uinta formation,
Upper Eocene, and about a mile south of the locality of the calcite
veins (G-3694) described on page 257, but approximately 200 feet
lower in the section.

The enclosing rock is a gray-green mudstone, believed by Dr.
Clark to belong to a sequence of near-shore deposits of a lacustrine
environment.

MACROSCOPIC DESCRIPTION

G-3844 is a pink, fine-grained calcareous concretion with irregu-
lar green zones. Lenses of red and green mudstone occur in the

272 FIELDIANA: GEOLOGY, VOLUME 13

similarly colored portions of the specimen. These lenses are gener-
ally just a few millimeters across but some are larger; one is 18 mm.
and extends, appropriately colored, from the pink across a green zone
and back into the pink-colored portion of the concretion. The clay
lenses are arranged in a step-like echelon series similar to the cor-
rugated clay lenses of the typical cone-in-cone structure.

Another concretion (G-3845) is highly irregular in shape and is
composed of a gray-green, fine-grained, impure, calcareous material
enclosing irregular lumps of gray mudstone. The surface of the
specimen is knobbly and ridged, indicating the irregular way the
carbonate was deposited as the concretion grew.

A similar concretion (G-3846), but with a silty base, in section
has a series of radiating, branching lines of lighter-colored material
originating at a point nearer the margin than the center. These
sheets, of finer grain and more calcite-rich, are continuous into the
ribs on the surface and are presumably related to zones of initial
deposition of carbonate.

G-3847 has a rough, globular shape but its surface is also ribbed.
A polished section, however, shows it to be composed of relatively
pure, coarsely fibrous calcite. The fibres are radially arranged, origi-
nating from a zone at the margin of the concretion. In this latter
zone the calcite is partly non-fibrous and partly fibrous, the fibres
being much smaller than in the main part of the specimen. Small
lenses of gray clay also occur in the marginal zone, and, where they
separate thin laminae of fibrous calcite, the structure is analogous
to cone-in-cone structure with its corrugated clay layers separating
conic scales.

MICROSCOPIC STRUCTURE

The thin section of G-3844 (slide no. 823) is mainly composed of
fine-grained homogeneous calcite with disseminated clay. In places
this passes into fibrous calcite only some 0.03 to 0.04 mm. long, in
which there are lenses of light brown clay up to 0.14 mm. thick (the
section did not cut any green-colored zone of the concretion). Al-
though the fibrous calcite and clay lenses are features possessed by
cone-in-cone structure, the latter is not recognizable as such in the
thin section.

Slide no. 819 (specimen G-3845) shows homogeneous calcite (ca.
0.06 mm. across) with disseminated clay, which passes into zones of
fibrous calcite with clay lenses. The fibres, up to 0.23 mm. long,
have varying orientations in different parts of the section but are

WOODLAND: CONE-IN-CONE STRUCTURE 273

invariably normal to the surface of associated clay lenses, some of
which are up to 8 mm. in diameter. In places the fibrous calcite
occurs in small conical tuft-like aggregates resembling the microcones
of typical cone-in-cone specimens. The association of fibrous calcite
with discrete clay lenses is again a feature reminiscent of cone-in-
cone structure.

The thin section (slide no. 820) of the radially fibrous concretion
G-3847 shows very dusty, spindle- or wedge-shaped, fibrous calcite
up to 6.5 mm. long and 0.7 mm. across. Many fine lines of dusty
inclusions enhance the radial structure. The radial structure is not
entirely regular, as conical tuft-like groups outlined by fine lines of
inclusions occur with their apices located at an inclusion of clay;
the tufts point toward the interior in many cases and toward the
exterior in others. In places, possibly where there are more impuri-
ties concentrated, the fibrous calcite is finer-grained and the wedge-
shaped grains form smaller tufted aggregates similar to the microcone
structure of typical cone-in-cone. The zone from which the overall
radial structure originates is composed of more or less equant calcite,
ranging in size from about 0.02 mm. to 0.1 mm. across. Although
these concretions do not possess good cone-in-cone structures, the
above descriptions clearly show that they do have both macro- and
micro-structures similar to those present in cone-in-cone specimens.
The presence of this incipient cone structure in these concretions,
together with the coned calcite vein from the same formation nearby
(p. 257) is very interesting, as they are the only examples of cone
structure known to me from undoubted non-marine sediments and
also the only ones of Tertiary age.

The fibrous calcite in the concretions is closely related to the dis-
crete lenses of clay or silt enclosed within the concretions. In the
non-fibrous portions the clay is present throughout as finely divided
particles. The development of incipient cone structure thus seems
to depend on the physical state of the sediment in which the car-
bonate is crystallizing at the time of crystallization.

38. Salina, Kansas (G-3566)

This characteristic development of cone-in-cone, about 27 mm.
thick, shows the fibrous character of relatively pure calcite. Cone-cup
surfaces are more evident than cone surfaces, and the former have
strong tooth-like corrugations, with steps near to vertical and up to
2.2 mm. high. Cone angles are about 20 to 25°.

274 FIELDIANA: GEOLOGY, VOLUME 13

39. Milan, Ohio (G-1540)

This is typical cone-in-cone. Some cones extend the entire thick-
ness of the specimen (53.9 mm.) ; others are shorter. The cone angle
appears to be very constant at about 26°. The fibrous calcite appears
to be oriented parallel with the cone walls.

40. Dudley, England (G-118)

This specimen is a very large cone ca. 185 mm. in height, made
up of a series of superimposed conic scales bearing strong concentric
calcitic clay corrugations which can be flaked off, and in places bear-
ing longitudinal striations. The corrugations increase in size toward
the base, where they are up to 4 mm. in breadth. In the lower part
of the specimen there is a complex of smaller (some about 48 mm.
high) interfering cones, which exhibit corrugated cone-cup surfaces
as well as cone surfaces. The base shows the arc structures of the
smaller cone bases. The main cone angle is 50°. Fibrous structure
is not evident, and fractured surfaces appear as structureless, fine-
grained calcilutite. Thin section study (slide no. 279), however, in-
dicates that the fine calcite possesses a texture and orientation similar
to other cone-in-cone examples. Shaly material coats the corrugated
cone and cone-cup surfaces.

A partial chemical analysis is given in Table I.

41. Black Hills, South Dakota (G-783)

Although both cone and cone-cup surfaces are present, the cones
are only partially developed because of mutual interference. The
cone angle is 40 to 45°. The cone-cup surfaces are strongly corrugated
and the cone surfaces also have an occasional transverse ridge. The
fibrous character of the cones is very evident; it produces the longi-
tudinal striations on the cone surfaces and on portions of the cone-
cup surfaces.

A partial chemical analysis is given in Table I.

42. Raton, New Mexico (G-2094)

The cones are well formed and cone-cup surfaces are corrugated.
The conic scales are clearly shown and thin to the apex of the
cone. The corrugations show more or less vertical surfaces that are
striated and suggest slip surfaces disposed in concentric arcs. The

WOODLAND: CONE-IN-CONE STRUCTURE 275

thickening of the conic scales toward the base of the cones might
account for the often-observed flaring of the basal portions of the
cones. In addition to the thickening of the overlapping conic scales
their increase in number away from the apex of the cone would also
develop a conic form.

43. Specimen of Unknown Origin (G-3567)

MACROSCOPIC STRUCTURE

The fine, fibrous structure of the layer (34.82 mm. thick) is very
evident. Cones are few and dispersed and show as individualized
cone-cups only; no actual cones are visible. The sides of the cups
flare toward their bases and have well-marked corrugations. The
calcite fibres of the wall lie parallel to the cup and at an angle to the
apparently vertical fibres in the surrounding matrix. The largest
cone-cup measures 32.62 mm. in depth with a base diameter of
19.90 mm. and a fibrous corrugation 1.64 mm. thick. The cone
angle varies from 12° near the apex to 52° in the central region.

MICROSCOPIC STRUCTURE, VERTICAL SECTION

The specimen shows a fine grain, which extinguishes in larger ill-
defined spindle-shaped areas between crossed nicols. In addition to
the microcones of clay there are conspicuous, corrugated, partially
coned layers of clay up to 0.23 mm. thick. A thin layer at the sur-
face toward which the cones point is a transition zone where the cal-
cite spindles are more irregular and where there is more clay.

44. Specimens of Unknown Origin (G-707A and B)

G-707A has a height of 53 mm., a base 33 to 35 mm. in diameter,
and a cone angle of about 35°. The base shows small cone-cups.
Annular rings are present on the surface of the cones; where the
rings are absent a longitudinally striated surface is evident.

G-707B is a large incomplete cone ca. 64 mm. high, which would
be about 103 mm. high by projection of the cone walls; its cone angle
is about 26°. The structure of composite conic scales is evident.

IV. CHEMICAL COMPOSITION

Harnly (1898) records several analyses of cone-in-cone specimens
from Kansas as follows (in percentages) : Si02= 1.46 to 5.84; Fe203 +

276 FIELDIANA: GEOLOGY, VOLUME 13

Al203=1.2 to 2.62; CaO= 54.13 to 54.64; C02= 33.07 to 42.06;
MgO=0.0 to 2.76.

Hendricks (1937) reports cone-in-cone from the Missouri Moun-
tain slate (Silurian), Arkansas, as being composed of a relatively pure
manganiferous siderite containing only small quantities of calcium
and magnesium.

Reis (1903, p. 214) quotes a number of analyses of cone-in-cone
specimens, with their carbonate content ranging from 70 to 90 per
cent. He also presents detailed analyses of a number of others, one
of which, from Staffordshire, England, is quoted in Table I. Three
specimens in the Museum's collection have been partially analyzed
by the late Mr. H. W. Nichols; these results are also given in Table I.

Table I

G-93 G-783

North East, Black Hills,

Pennsylvania South Dakota

CaCOs 67.89 75.61

MgC03 tr 1.68

FeCOs 17.27 11.40

MnC03 + +

Residue + +

+ = not reported.

G-93 and G-783 are composed of calcite with some substitution
of Ca by Fe and Mg. The other two examples would appear to be
composed of a mixture of carbonates or a carbonate approaching an
ankerite, with substantial substitutions of (Fe, Mn) for Mg and with
Ca in excess of the 1:1 ratio for Ca: (Mg, Fe, Mn).

Some approximate determinations of carbonate content were
made by weighing the residues after treatment of several specimens
in warm hydrochloric acid (1:1). A bulk sample (G-3547) from
Woodland Valley, Indiana, has a residue of 24 per cent and thus an
approximate carbonate content of 76 per cent. The residue in the
non-coned central portion of the concretion (G-3586) from near
Judique Village, Cape Breton Island, Nova Scotia, is 28.4 per cent,
while that from the coned portion in the upper part of the same
specimen is 17.4 per cent.

In two other specimens the clay in the lenses forming the macro-
scopic cones was separated from the fibrous carbonate. Determina-
tions of residues made on each fraction were as follows:

G-118
Dudley,
England

Staffordshire,

England
(Reis, 1903)

49.67

52.28

17.27

27.12

17.53

10.58

+

2.59

+

8.44

WOODLAND: CONE-IN-CONE STRUCTURE 277

Table II

Dotson's Branch,

Indiana (G-3554)

Tracy, Iowa (G-3561)

Fibrous

Fibrous

Clay

carbonate

Clay

carbonate

%

%

%

%

Soluble

52

85

7

96

Residue. . .

48

15

93

4

A complete separation was not achieved. The Dotson clay frac-
tion contains considerable carbonate, but this may have been caused
mainly by contamination with fibrous carbonate rather than by car-
bonate content within the clay lens. The Tracy clay fraction con-
tains but little carbonate. The fibrous carbonate fractions both have
very high soluble proportions, the Tracy specimen being the purer
carbonate. This is in agreement with the microscopic examination
in which the Dotson's Branch specimen is seen to have abundant
microcones of fine clay within the macrocones (see p. 206).

The carbonate content of the cone-in-cone specimens is quite
similar to that of non-coned carbonate concretions; for example, the
residue of a sample of a large concretion (Li-4703) occurring within
gray shale at the Mecca Quarry, Indiana, and stratigraphically close
to the Woodland Valley cone-in-cone horizon is 12 per cent, while
that of a concretion (Li-4706) from black sheety shale also from
Mecca Quarry is 14 per cent. The bulk carbonate content of cone-
in-cone specimens is thus similar to that of calcareous concretions
commonly found in shales.

V. GRAIN ORIENTATION

A number of grain orientation studies were made from thin sec-
tions cut normal to the cone axes. "C" crystallographic axes were
determined on a universal stage by means of the conoscopic method.
These axes were plotted on a Schmidt net and contoured; the re-
sultant stereograms are shown in figure 86.

The grain size is so small in the Kentucky (slide no. 270) and
Woodland Valley, Indiana (slide no. 254), specimens that the cen-
tered conoscopic figure at each interval of the traverse is usually
poorly defined and is probably the result of an aggregate of grains.
However, the scatters obtained are believed to reproduce the scatter
of the "c" axes.

The "c" axes are by no means vertical; the angular spread, corre-
sponding to a conical angle, varies from 16° to 20° in the Tracy,

278

FIELDIANA: GEOLOGY, VOLUME 13

Fig. 86. Petrofabric diagrams of cone-in-cone; "c" axes of calcite plotted on
the lower hemisphere of a Schmidt stereonet and contoured: a, 30 axes, Woodland
Valley, Parke County, Indiana (contours: 3 %, 7 %, 13 %, 20 %, 27 %); 6, 100
axes, Tracy, Iowa (contours: 1 %, 5 %, 25 %, 50 %, 75 %); c, 102 axes, single
cone, Kentucky (contours: 1 %, 5 %, 20 %, 46 %, 60 %); d, 248 axes, concretion
with trilobite, Deseret, Utah (contours: Y2 %, 1 %, 3 %, 5 %, 9 %, 13 %, 17 %).

Iowa, specimen (slide no. 255) to a surprising 60° for the trilobite
from Utah (slide no. 262). The axes also do not fall on a small circle
centered around the cone-in-cone axes as they would if the grains
were oriented parallel to the conical surfaces. Rather, the orienta-
tions have a brush-like pattern or an incomplete radial structure.
The angle of maximum spread of "c" axes agrees well with the meas-
ured cone angles of the Iowa and Indiana specimens and with the
cone angle near the apex of the Kentucky specimens. The spread of

WOODLAND: CONE-IN-CONE STRUCTURE 279

60° in the trilobite is, however, much greater than the cone angle
of 26° measured in the vertical thin sections. The grains with the
largest angle to the cone-in-cone axis may represent the less regular
grains of the very "dusty" areas, particularly around the cones mark-
ing the margins of the trilobite axis.

VI. PREVIOUS VIEWS ON CONE-IN-CONE STRUCTURE

Cone-in-cone structure has certainly been known and described
for over a century and there have been many attempts to explain
its origin. In 1859 Sorby (1860) gave an excellent brief description
of its microscopic structure and suggested that it is a concretionary
structure, formed after the deposition of the rocks in which it occurs
by the crystallization of calcium carbonate and other isomorphic
bases, the crystals forming almost entirely on one side along an axis
in a fan-shaped manner to produce a conical shape.

Tarr (in Twenhofel, 1932) and Cayeux (1935) review at some
length the work previous to their own publications and include good
bibliographies. Mention might be made here of the following few
papers. Cole (1893) holds that the structure is produced when crys-
tallization starts at a number of points on the surface of a bed or in
the interior of a concretion and growth radiates out and tends to form
a cone from each point. The serrated clay between the cones is the
residue forced aside during the crystallization. He further states
that it is highly probable that the "c" axes of the calcite are parallel
to the axes of the cones. Gresley (1894) gives good descriptions and
figures of specimens from the Devonian near Erie, Pennsylvania, and
these are identical to some available to myself. He attributes the
structure to concretionary concentration of calcium carbonate, which
induces pressure among the particles so as to form cones and also
involves the partial expulsion of the contained clay, which, owing to
the radial pressure, forms horizontal rings or ridges.

Reis (1903) describes and figures the structure in great detail and
has a long and very involved discussion of its origin. Briefly, he
holds that it is caused, over a long period of time, by the enrichment
of carbonate by concretionary action often accompanied by the de-
composition of organic residue. The accretion begins soon after the
laying down of the beds under some superimposed pressure and is
related to the diagenesis of clay-rich, carbonate solution-bearing
layers. The crystallization tends to form aggregates approximating
the crystal form. Contraction tensions produce polygonal pyrami-
dal surfaces of "splitting." Entry of water causes solution, which

280 FIELDIANA: GEOLOGY, VOLUME 13

in turn forms the clay residues, producing the stepped conical clay
layers. He holds that the vertical surfaces of the "steps" are slide
surfaces, and that movements of portions of the mass are also indi-
cated by dislocations of fine horizontal bands. Later Reis (1914)
abandons solution as playing a part in the origin of the clay layers
and considers that they are formed by the growth of the calcite,
which pushes the clay into the conical layers. Fine bands which
cross the cones approximately parallel to the bedding he likens to
rhythmic deposits in gelatin produced by Liesegang. He explains
the interruptions and displacements in the bands as due to different
rates of crystallization.

Keyes (1896) considers the crystallizing force of calcite as respon-
sible for the production of cones and states "... that even the clay
is pressed into the form assumed under normal conditions by the
calcite." Richardson (in Lang, Spath, and Richardson, 1923) has
studied the fibrous calcite veins, known as "beef," which occur in the
Lower Lias of the Dorset coast, England. The "beef" shows cone-
in-cone structure, which is more complex the greater the thickness
of the vein and is frequently associated with calcareous concretion-
ary nodules. He suggests that rapid crystallization of the calcite
fibres on each side of the central parting takes place under a vertical
principal stress caused by the weight of the superincumbent strata
and under lateral stresses caused by resistance to lateral growth of
the fibres. The state of stress produces inclined planes of maximum
shear (conical in three dimensions), which act to inhibit crystal
growth in such a way that the fibre cannot cross such a plane. In
support of this, he states that the cones penetrate the total thickness
of the "beef" vein without interference by the central parting as
shown in his figure 5. However, his figure 6 does not support this,
for the cones on either side of the parting appear to be independent,
and Lang (op. cit., p. 52) states that "All seams are double, and the
cones of each layer interpenetrate at the junction." Tarr (1932,
p. 726) also states that ". . . the cones were on both sides of the
parting but did not cross it."

Linck (1930) suggests that cone-in-cone structure forms as the
result of the crystallization of a gel-type sediment in which calcium
carbonate has been maintained in a colloidal state by the action of
protective colloids, with loss of water and decrease in volume. It is
difficult to see how the crystallization of a pre-existing gel could form
a trilobite image in the coned calcite as in the case of the Elrathia
concretion (p. 241). The Cunningham Brook specimens (p. 251)

WOODLAND: CONE-IN-CONE STRUCTURE 281

clearly prove that the formation of the coned calcite veins resulted
in expansion and separation of pre-existing sedimentary layers. This
occurred after sedimentation and thus the coned calcite could not
be formed by the crystallization of a pre-existing sedimentary col-
loidal gel.

Herrmann (1930) also considers that fibrous crystallization takes
place but under the influence of pressure directed from all sides.
The pressure is a result of swelling of the surrounding clay. Conical
slip surfaces, along which clay layers arise, are also produced in the
carbonate-rich concretionary body and there are differential move-
ments of the cones.

Tarr (1932) holds that cone-in-cone occurs in massive material
as well as in the more usual fibrous calcite. However, this appears
to be a mistaken view. A specimen he describes from Dudley, Eng-
land, is almost certainly composed of fibrous calcite as is also the
specimen (G-118) from Dudley in the Museum's collection and
described above (p. 274). He also mentions specimens from Kansas
and Kentucky as being massive. I cannot comment about these,
although specimens from these two states in the Museum collection
are, again, of fibrous calcite. The cone structure in coal, a fine ex-
ample of which is in the collection (G-450), is an entirely different
structure and should not be confused with true cone-in-cone (see
p. 190). Likewise, the percussion cones in quartzite that Tarr men-
tions should not be considered as belonging to true cone-in-cone but
to pressure-induced structures, such as those induced by striking
homogeneous material (fig. 26) and shatter cones (fig. 25).

Tarr also states that the cones are later than the fibrous layer in
which they occur, although his "proofs" are far from convincing
(1932, p. 727). Tarr invokes pressure as the main agent, accom-
panied by solution which gives rise to the annular rings of clay and
clay films as insoluble residues. In the cases of coal and quartzite
he excepts solution as playing a role. He originally (1922) held that
a fibrous character was essential, but later (1932) refuted this on the
erroneous basis of the cones in massive material, although he still
considered a fibrous nature very important (1932, p. 733) when
present. The cleavage angle of calcite Tarr also thinks important
in spite of the fact that he establishes (1932, p. 719) that the con-
ical angles in "beef" depart widely from the rhombohedral cleavage
angle of calcite. He even states that the reason why the cones have
their bases at the surface of a layer instead of their apices, as in the
case of percussion cones, is because of the cleavage in calcite. As

282 FIELDIANA: GEOLOGY, VOLUME 13

to the source of pressure, Tarr discards the pressure caused by the
volume increase when aragonite changes to calcite, the pressure pro-
duced by growing concretions, the pressure of diastrophic disturb-
ances, and the pressure of crystallization forces. The weight of
overlying beds is his remaining source, and he details (1932, p. 729)
his reasons for believing in a differential vertical pressure. Tarr's
point 2, ". . . the cones are dominantly on the upper side of a layer
with their bases upward, though smaller ones occur also on the lower
side, with their bases downward," is by no means universal. Like-
wise, his point 3, ". . . the most perfect cones have apical angles that
approach those of the ideal cones developed in testing the crushing
strength of materials, that is, angles of 70 to 110°," and point 4,
". . . the apical angles in cone-in-cone are nearly that of the rhombo-
hedral cleavage of calcite (the cleavage of calcite would give an apical
angle of 106°)," are also dubious in view of the great departures of
conical angles from these values. With respect to Tarr's point 8,
". . . the surface of a layer of fibrous calcite containing cone-in-cone
commonly shows concentrically curved fracture lines that are the
result of pressure," the curved lines are more than mere fracture
surfaces; in all of the specimens that I have examined the curved
lines represent intersections of partially conical layers of clay.

Tarr's claim that solvent action along the shear planes removes
carbonate, leaving behind an insoluble clay residue, is open to doubt.
He postulates that the annular rings of clay are produced when solu-
tions move down the shear planes and attack the upper edges of the
calcite fibers first, thus producing greater solution at these points
and resulting in the stepped character of the clay (see Tarr, 1932,
fig. 107) . However, this applies only to cones with their apices point-
ing downward. In the case of those with their apices pointing up-
ward, downward-moving solutions would produce clay steps on the
inner surface of the conical clay layer — a position I did not find in a
single specimen. Both types of cones are identical in structure and
are mirror images. Following Tarr's explanation, the solvent must
thus move up the conical shears of all cones pointing upward and,
of course, down the shears of cones in the reverse position. This
seems most unlikely. Solvent action thus does not appear to be
adequate to explain these characteristic stepped clay structures.

Cayeux (1935) attaches importance to the occurrence of cone-in-
cone in materials other than calcite. It should be noted in this re-
spect that he quotes Gresley (1894) for many of the diverse media.
Actually, Gresley clearly considers cone-in-cone structure to have

WOODLAND: CONE-IN-CONE STRUCTURE 283

been originally formed of calcite in all cases. In a footnote Gresley
states that his specimens of other mineralogical composition "... are
unquestionably what may be called re-altered products, that is, 'ter-
tiary' formations . . .," in other words, replacements of calcite.
Cayeux also mentions gypsum and coal. The former is also recorded
by Tarr (1932), who considers it a replacement of calcite. As far as
the cone structure in coal is concerned, I have already stated (p. 190)
that it is an entirely separate structure and should not be considered
along with true cone-in-cone.

In the case of specimens composed of carbonate Cayeux argues
that if only clay impurities were concerned in the conical surfaces the
structure could be explained solely by the forces of crystallization of
calcium carbonate. Because quartz grains showing important dis-
placements from their original positions occur in the carbonate of
one specimen, he considers that external mechanical forces, such as
lateral compression, must be involved. An impure mass of carbonate
held between resistant planes which resist vertical displacement of
the material has suffered a lateral compression. The latter has
caused a large-scale recrystallization of the carbonate along with
the elimination of impurities of small dimensions. Thus, siliceous
specimens from HeVault he considers to be composed of normal
micro-quartzite and the cone-in-cone structure to have been formed
exclusively by dynamic means, causing a more or less geometric
arrangement of micaceous material (but see p. 246).

Denaeyer (1939, 1940b) claims to have reproduced cone structures
by tensional forces applied to a flattened ball of plastic clay and
suggests that even gentle warping of beds would suffice to cause
local zones of tension. Recrystallization under the influence of the
directed tension results in the preferred orientation of the fibrous
calcite of calcareous cone-in-cone (1940b, p. 318). He describes many
occurrences of cone-in-cone (1940a, c, 1947) and elaborates his idea
(1945) that penecontemporaneous tectonic deformation causes trac-
tion forces in muddy plastic rocks. He suggests (1946), however,
that the traction forces that form cone-in-cone on septarian nodules
are not due to tectonics but to variation in the volume of the nod-
ules during concretion formation and to the adherence of the nodules
to the enclosing strata.

Bonte (1942) considers cone-in-cone to be the result of concre-
tionary action caused by directed diffusion phenomena around de-
caying organic matter, and Gay (1942) outlines a theoretical model
of diffusion and crystallization to explain the conical forms. This

284 FIELDIANA: GEOLOGY, VOLUME 13

model is, however, too simplified to explain the complexities of struc-
tures actually found in cone-in-cone specimens. Thoral (1942) also
believes that the structure is due to early concretionary activity
connected with decomposition of organic matter and that the diffu-
sion and thickness of the concretion are related to the grain size of
the enclosing sediment.

Bonte (1945a), while adhering to his original views on the origin
of the conical structure, considers that the concentric rings or steps
that characterize cones are formed by a mechanical process. Com-
pression causes part of the coned mass to separate by slipping along
the length of the calcite fibres and by transverse tearing of the fibres;
then foreign amorphous or crystalline material is interposed to form
the normal rings. In some cases the steps are deformed or partially
flattened to permit the dislocation of the cones. Similarly, Bonte
(1952) explains the coned calcite veins or "beef," the fibrous calcite
of which crystallized rapidly and concurrently with the opening of the
walls of the vein.

For a number of years Bonte and Denaeyer held opposing views
on the origin of cone-in-cone, but in 1947, in collaboration with
J. Goguel, they produced a mutually agreed theory which combined
portions of each of their earlier ideas. This mutual theory (Bonte,
et ah, 1947) may be summarized as follows: The volume of a nodule
or a bed increases during recrystallization or concretionary growth,
but the horizontal dimension is prevented from increasing by the
opposition of the neighboring sediments. This results in an augmen-
tation of horizontal pressure, although the vertical pressure remains
essentially constant. In the case of cone-in-cone layers on septarian
nodules the authors suggest that tangential pressure exceeds the
radial pressure, so that there is traction in the radial sense (presum-
ably in the directions of minimum stress). Denaeyer (1952) inter-
prets cone-in-cone in calcite veins, oblique or vertical to the bedding,
as a consequence of tension forces exerted on the calcite during crys-
tallization as the fissure opened. Further, he suggests (1954) that
reduction in volume of sediments by dehydration causes separation
of the strata. Simultaneous lateral secretion results in the formation
of double or multiple layers of calcite with "beef" structure ("fibro-
conique") and occasionally with cone-in-cone. The transport or
separation of argillaceous impurities during the lateral secretion as-
sists in the production of the stepped films. The latter show the
small internal slides or tears that follow a conical form and are pro-
duced by the parting of the walls of the fissure. The oriented crys-

WOODLAND: CONE-IN-CONE STRUCTURE 285

tallization of calcite is due to the action of a directed traction
(tension). This explanation may be extended to thick lenticular
beds of cone-in-cone. In the case of isolated nodules Denaeyer still
considers that the lateral opposition of the sediments should not be
forgotten (presumably for the production of radial traction forces).

The concept that a tractional force causes the orientation of
fibrous calcite and the conical toothed or stepped clay layers has
been the consistent mechanical explanation of Denaeyer. Bonte,
Denaeyer, and Goguel (1947) hold that the concretionary growth
itself is responsible for the orientation of the calcite and the cone-in-
cone structure, albeit by the production of traction forces. Denaeyer
(1954) considers the traction forces, at least in the case of veins and
beds of cone-in-cone, to be externally produced, causing the Assuring,
lateral secretion, and then the displacements in the fibrous calcite
that form the steps in the clay layers.

I, too, believe that the cone-in-cone lenses and layers had a con-
cretionary origin, and consider that the concretionary growth itself
is responsible for the structure. But the operation of tractional forces
to form the cones seems unlikely. One may ask why cone-in-cone is
not present on all concretions or veins where similar forces should be
operating during formation. Growth of a concretion is an expansion
process. It is likely that the direction of maximum stress in and
around such a growing body is radial in a spheroidal or lensoid con-
cretion and vertical in a horizontal vein or layer. The minimum
stress directions would then lie parallel to the surface of the growing
body. The veins on the Cunningham Brook specimens (described
on pp. 251-257) strongly indicate that the force of crystallization
of the calcite pushed the sedimentary layers apart and not that the
latter were dilated by some external process (dehydration or tec-
tonics). According to Denaeyer (1954) the traction forces can only
displace the clay layers after they have formed. They would then
be embedded in the crystalline calcite. There is no evidence that
tensional forces have operated to produce the steps in the clay by a
series of displacements, or that these displacements are greater in
the earlier-formed part (the inner zone in the case of coned layers or
lensoid concretions) of the structure. In fact, the reverse is true,
for the displacements are greater toward the latest formed zone.

Twenhofel (1950, pp. 605-611) follows Tarr in ascribing pressure
from the load of overlying sediments and solution as the agencies
that cause cone-in-cone structure. Pettijohn (1957) considers pres-
sure instrumental in forming cone-in-cone, not by the weight of

286 FIELDIANA: GEOLOGY, VOLUME 13

overlying beds but by the forces produced by concretionary growth
acting on earlier-formed layers. Solution is then responsible for
forming the conical clay layers. Weller (1960) holds that cone-in-
cone is a shear structure produced by the weight of overburden act-
ing on calcite fibres, which are secondary material formed before
much consolidation has taken place. Concentric shears are formed
around fairly evenly spaced centers and are accompanied by solution
along the principal shear planes.

Morawietz (1961), in an interesting description, suggests that
cone-in-cone limestone layers develop very early in diagenesis in
water-rich, hydrogen sulfide- and hydrocarbon-bearing, partly cal-
careous muds with about 70 per cent pore volume. Superposed
pressures are unnecessary; the carbonate crystallizes as a result of
lowering of solubility as the sediment dries out, due to temporary
uplift above sea level. The resultant heating, degassing, and evapo-
ration cause crystallization to start suddenly, to be rapid at first and
then slow down. Morawietz figures (op. cit., p. 239) double cone-in-
cone layers, with their apices directed away from the center and
with a central clay parting. This is the only case of such an arrange-
ment known to me either from the literature or in the Museum's
collection. In all the latter the cones of a double layer point toward
the center. Morawietz states that the upper and lower cone-in-cone
layers grew toward each other and finally compressed and imprisoned
the central clay layer between them. The proximal (apical) portion
of each layer is, however, finer-grained and more clay-rich than the
distal. He believes that there was some expansion, particularly of
the upper layer of the double cone-in-cone, over the thickness of
original sediment. The reason for the cone-in-cone structure is not
explicitly discussed, but Morawietz considers it (op. cit., p. 246) to
result from rapid crystallization of calcium carbonate in radiating
tuft- and cone-like needle aggregates.

Miiller (1962) considers cone-in-cone structure in a concretion
from the Muschelkalk to have been the result of recrystallization of
a colloidal concretion under the influence of confining pressure.

VII. DISCUSSION OF LITERATURE

The above survey of the literature shows that some confusion
has attended the description of the occurrence of cone-in-cone; aris-
ing from this confusion conflicting theories have been proposed. In
my opinion the term "true cone-in-cone structure" should be re-

WOODLAND: CONE-IN-CONE STRUCTURE 287

stricted to occurrences composed essentially of carbonate. Speci-
mens having the characteristic structure of these types but now
composed of other minerals, such as the siliceous examples in the
Museum's collection, must be regarded as replacements, as indeed
Gresley (1894) recognized long ago. Fibrous texture of the calcite
is also a constant feature and must be regarded as an essential factor
in the origin of the structure.

Pressure both from external forces and from crystallization of cal-
cite has been invoked as imposing cone-in-cone structure on already
crystalline material (Tarr, 1932; Cayeux, 1935; Petti John, 1957;
Weller, 1960). The complex character of cone-in-cone, as revealed
in most of the specimens described above, particularly the micro-
scopic structure and the relationship between the microcones, the
impurities, and the fibrous calcite, indicate that the cones cannot
be explained simply as late shear structures. Stress resulting from
volume increase caused by inversion of aragonite to calcite has also
been suggested as an agent (Tarr, 1922). It is difficult, however, to
envisage how the intricate micro- and macrocone forms of the clay
could result from such a force. If aragonite was the first to form,
then the cones must have been formed at that time, and the later
change to calcite was inconsequential. Moreover, there is no evi-
dence that the carbonate initially crystallized as aragonite. Trac-
tional forces have been invoked by Denaeyer (1939, 1940b, 1954),
Bonte, et al. (1947), and Bonte (1952) to orient the calcite, form the
conical structure, and produce the stepped nature of the clay layers.
The operation of such forces seems inadequate to explain the struc-
ture and is unlikely to have operated, at least in nodular concretions,
for the reasons explained (p. 285). A mechanism that may appear
to explain satisfactorily some types of occurrences is, nevertheless,
deficient if it is not able to account for other occurrences possessing
the same essential characteristics.

Action of solution has been called upon to help explain the con-
ical corrugated clay layers (Reis, 1903; Tarr, 1932; Petti John, 1957;
Weller, 1960). Certainly the complex micro-fabric cannot be ex-
plained in this way. The evidence of the specimens from New Bruns-
wick (p. 251) clearly shows that solution was not involved in the
production of the clay layers and that the latter represent original
sedimentary laminae.

W. A. Richardson (1923) considers that a stress field caused by
superposed beds and the force of crystallization of the calcite set up
conical shear stresses that controlled the course of crystallization of

288 FIELDIANA: GEOLOGY, VOLUME 13

the calcite so that the growth of individual fibres stopped at the con-
ical shear surfaces. While this suggestion of the simultaneous opera-
tion of external stress and force of crystallization has merit, it is
incomplete in that it does not explain the conical clay layers and fails
to explain why cone-in-cone does not occur in all cases of the crystalli-
zation of calcite in a sediment or rock; for example, in all calcareous
concretions and in all fibrous calcite veins. Both Dawson (1868)
and Marsh (1868) interpret cone-in-cone as the effect of pressure on
concretionary action, although Dawson does not specifically say
whether the compression acted at the time of the crystallization or
later, while Marsh considers that compression and crystallization
were contemporaneous.

Crystallization of calcite has been held by many geologists to be
the essential cause of cone-in-cone. Sorby (1860), Cole (1893),
Gresley (1894), Keyes (1896), and Reis (1914) consider that the
way the fibrous calcite crystallized is responsible for the cone struc-
ture. The latter four authors explicitly state that the crystallizing
force of calcite pushed the clay into conical layers. Recently Mora-
wietz (1961) considers that rapid crystallization in radial conical
forms produces the structure, but his only reference to clay is to that
compressed between the two layers of a double cone-in-cone seam.

VIII. RESULTS OF THIS STUDY: THE ORIGIN OF
CONE-IN-CONE AND DISCUSSION OF REQUI-
SITE CONDITIONS FOR ITS FORMATION

The specimens described in this paper provide clear evidence that
cone-in-cone structure is essentially produced by crystallization and
fibrous growth of calcium carbonate and is concretionary in origin.
The following questions consequently arise as to the particular con-
ditions controlling its appearance:

1. What causes the initial deposit of calcium carbonate?

2. Where does the calcium carbonate come from?

3. At what stage does the concretionary action take place rela-
tive to the deposition and consolidation of the enclosing sediment,
and what is the condition of the sediment?

4. What controls the type of fabric, that is, the fibrous habit as
compared with the non-fibrous habit of non-coned concretions or
as compared with the non-coned layers of concretions associated
with coned layers?

WOODLAND: CONE-IN-CONE STRUCTURE 289

5. How much expansion over the original thickness of sediment
is involved?

6. What, if any, is the influence of the vertical pressure of over-
lying beds and what is the influence of the crystallizing force of
calcite?

7. What controls the size of cones, the size of the conical angles,
and the individualization of the cones?

8. What causes the cessation of growth?
These questions will now be discussed in turn.

1. What causes the initial deposit of carbonate? The deposition
of calcium carbonate in cone-in-cone may be controlled entirely by
physico-chemical conditions, such as the available supply of calcium,
activity of CO2, or pH of the environment. However, the decay of
organic matter has been cited by many as a possible initiator of the
deposition at localized centers. Lalou (1957) reports on the experi-
mental crystallization of carbonates by bacterial action on organic
matter and suggests that, in addition to the release of CO2, the re-
duction of sulfates and production of H2S with concomitant increase
in pH is essential to the deposition. A relationship between the de-
cay of organic matter and the occurrence of cone-in-cone has been
noted by Reis (1903), Bonte (1942), Gay (1942), Thoral (1942),
Brown (1954), Harrington and Leanza (1957), Bright (1959), and
Morawietz (1961). Stubblefield (1930) reports Upper Cambrian cone-
in-cone concretions containing trilobites. Lang (in Lang, et al., 1923)
describes ammonite shells that occur in the center parting of cone-
in-cone layers ("beef") and also cone-in-cone one-fourth inch thick
with ammonite ornamentation on both upper and lower surfaces.
David (1952) also describes fossils that occur in the middle of coned
"beef" layers, the outside surfaces of which have more or less faith-
ful images of the contained organisms. Steinmann and Hock (1912,
p. 190) mention orthoceratids that occur within cone-in-cone con-
cretions. Fossils are closely associated with many of the cone-in-
cone specimens described in this paper. In addition, the activity
of H2S is shown in many specimens by the very common occurrence
of pyrite and, in a few cases, of sphalerite. The decay of organic
matter may thus have been the initial cause for the precipitation of
the carbonate by establishing favorable physico-chemical conditions.

2. Where does the calcium carbonate come from? The source of
the carbonate is a difficult question. Undoubtedly in some cases

290 FIELDIANA: GEOLOGY, VOLUME 13

the environment of deposition was poorly supplied with carbonates;
the concretionary cone-in-cone represents a concentration by diffusion
from the enclosing sediments, with perhaps some carbonate coming
from the original content of the circulating interstitial water. Pantin
(1958) suggests that the carbonate of the concretion he describes was
derived from a clastic source and was concentrated by recrystalliza-
tion. In other cases the environment of deposition was or soon be-
came enriched in carbonate, possibly by the activity of organisms,
and the cone-in-cone layer represents a relatively widespread limy
horizon. In some examples — Woodland Valley, Dotson's Branch,
Barren Creek, and Montgomery Creek, Indiana — there has been re-
placement of shell by pyrite in the sediment above or adjacent to
the cone-in-cone; this replacement may have released some carbonate
to the growing cones.

3. At what stage does the concretionary action take place relative
to the deposition and consolidation of the enclosing sediment, and what
is the condition of the sediment? The microscopic structure of the
cone-in-cone and in particular the displacement of the clay parti-
cles to the microcone surfaces suggest that the sediment was by
no means consolidated at the time of cone formation. Probably it
still had a high water content, and the crystallizing calcite was easily
able to insinuate itself among the particles and move them. The
disposition of the clay as fine particulate matter and its distribution
pattern in the case of the Elrathia specimen (p. 238) support this view.
On the other hand, the Cunningham Brook specimens (G-3640-42,
p. 251) show that the growth of the calcite not only displaced clay
particles into very fine conical films but also displaced layers of
clay into conical or saucer-shaped forms. Presumably these layers
were sufficiently compacted to behave as coherent lenses, although
there probably was further compaction caused by the calcite crystal-
lization and perhaps subsequently by loading. The corrugated clay
lenses of complex cone-in-cone are considered analogous to those of
Cunningham Brook.

However, if the sediment is compacted beyond a certain degree,
the calcite growth then takes place along a bedding contact and the
resulting fibrous but unconed vein grows by separating the two op-
posing surfaces by the force of crystallization. The calcite is very
pure and there are no finely divided clay particles present to form
microcones and no clay lenses to form the thicker corrugated clay
layers outlining macrocones. Specimen G-3564 (described, p. 237)

WOODLAND: CONE-IN-CONE STRUCTURE 291

conforms to this origin except that along one boundary there are
small saucer-shaped clay lenses that have been detached by the cal-
cite growth. This vein is typical of epigenetic veins, which may be
formed at any time after consolidation and diagenesis of the enclosing
sediment, depending on the supply of material and perhaps depth of
burial. The veins in the specimens from Quebec (G-3562-64, p. 247)
probably represent an intermediate type in that they contain very
little included material; there is minor coning outlined by fine clay
immediately adjacent to the initial growth plane, where the calcite
is fine-grained.

4. What controls the type of fabric, that is, the fibrous habit as com-
pared with the non-fibrous habit of non-coned concretions or as compared
with the non-coned layers of concretions associated with coned layers?
The fabric of post-consolidation calcite veins is commonly fibrous,
with the long dimension of the fibres normal to the walls of the
veins (Grout, 1946). This is also a crystallographic preferment,
as the "c" axes are virtually parallel to the long dimension of the
fibres. The reasons for this particular fabric habit are complex
but presumably include the anisotropic properties of the crystal
lattice and physical and chemical properties of the environment.
Turner (1949) notes that in the growth fabric of calcite the "c" axes
are perpendicular to the longest grain dimension, which is parallel
to the direction of greatest ease of growth. This is contrary, how-
ever, to the fabric of cross-fibre veins. Griggs, et al. (1960) have
shown experimentally that calcite recrystallized under non-hydro-
static stress tends to show the "c" axes parallel to the maximum
principal stress (see also Kamb, 1959, p. 160) and, further, that the
"c" axes of new grains tend to be at an angle of 25° to 30° to those
of the host grain. The pressure-temperature conditions of the ex-
periments certainly were far from those that exist during the growth
of cone-in-cone, which must take place at near-surface temperature
and pressure. However, the factors controlling the calcite orienta-
tion (p. 277) in cone-in-cone may be similar.

In the case of a watery mud with an exceedingly fine meshwork
of water-filled spaces between the clay particles, precipitation of cal-
cium carbonate (initiated by the development of the right conditions)
may begin at numerous randomly distributed nucleation points. As
a consequence the grain size will remain tiny. The clay particles
will act to shield the small crystals against much increase in size, so
that the interstices are soon filled by a multitude of tiny grains; a

292 FIELDIANA: GEOLOGY, VOLUME 13

compact structureless concretion results. Growth of such a mass
will continue peripherally as long as the supply of carbonate and the
other physico-chemical conditions permit. In the case of the coned
concretion G-151 (see p. 222) the form of the crystallized calcite
varies from the non-coned center to the coned exterior. This dif-
ference appears to result from the physical condition of the clay at
the time of crystallization. In the coned region the clay had been
somewhat compacted (so that more or less compacted layers or lenses
were present) at the time calcite crystallization commenced. Nucle-
ation was concentrated on the surfaces of these lenses and ensuing
growth forced the lenses apart. The separation between clay and
calcite, however, was by no means perfect, as there was still consid-
erable "looseness" to the clay; much of the clay was incorporated
into the calcite mostly inter-granularly and perhaps intra-granularly
when grain size increased. The small calcite grains were less crowded
by clay particles than were the grains in the non-coned zone, and
consequently continued growth was possible through a supply of ions
to the free surface. Growth on the crystal surface away from the
clay lens probably would have been favored, particularly as there
would have been competition laterally and interference by neighbor-
ing nuclei. Thus could have arisen a fibrous growth normal to the
surfaces of the clay lenses, and this would have been directed out-
ward from the central non-coned concretion.

The lattice orientation is more difficult to explain. It possibly
arises because of a tendency of calcite to crystallize with the "c"
axis lying in the direction of maximum principal stress and, there-
fore, normal to the clay lenses, which are approximately parallel with
the bedding. Kamb (1959, p. 156) on theoretical grounds states that
the stable orientation of calcite growth is for the "c" axis to be per-
pendicular to the interface between crystal and fluid and to parallel
the unique stress axis. Nucleation on the surface of clay lenses thus
results in the "c" axes being oriented normal to the lenses.

Growth of certain grains may be favored over their neighbors,
with the result that they grow larger and their free surface is able to
expand normal to the "c" axis more readily and to take on a flam-
boyant pattern of growth. A further influence on growth may be
surface effects that cause new grains to grow with their "c" axes at
an angle to that of the flamboyant grain (Griggs, et al., 1960). Thus
would arise a multitude of tuft-like aggregates such as characterize
the complex cone-in-cone and give rise to the orientations seen in the

WOODLAND: CONE-IN-CONE STRUCTURES 293

fabric stereograms (fig. 86). Subtle variations in the factors that
control nucleation and growth rate lead to variations of grain size.

The establishment of more or less coherent clay lenses is thus
necessary for the development of complex cone-in-cone. It is likely
that this very early diagenetic effect arises in a number of ways.
First, there may be original variations in the nature of the layers of
sediment such that some layers develop more compact lenses than
others (fig. 87, a, b) . This may explain the examples in which good
cone-in-cone structure grades laterally into less well-defined zones
(Woodland Valley, p. 197) or in which small patches of microcones
grade into a more homogeneous concretionary structure (Velpen
limestone, p. 218). Secondly, compaction of the sediment by the
overburden during crystallization of the carbonate may explain the
passage of a non-coned concretion through a fine-grained transition
zone to a well-developed cone-in-cone layer (fig. 88, a, b). Thirdly,
the growth of a non-coned concretion may cause compaction of the
peripheral sediment layers until a stage is reached which favors the
development of fibrous calcite and thus of a coned layer (fig. 89, a-c) .
This assumes that an expansion of volume attends the concretionary
growth and that the force of crystallization causes the compaction.
Force of crystallization is a well-known phenomenon; evidence of
its action in sediments is clearly shown by Folk (1962), who figures
shells forced apart by the growth of fibrous calcite.

Variations in the physical conditions of the sediment, such as the
degree of compaction, thickness, and number of discrete laminae, at
the time of crystallization, coupled with the physico-chemical factors
of nucleation and growth, control the particular fabric, structure,
and complexity of each cone-in-cone occurrence. Nucleation oc-
curred on the ventral surface of the Elrathia (fig. 67) and growth
proceeded downward, either by lifting the carapace or by compact-
ing the sediment beneath or both. Fine dust was incorporated into
the vein and influenced the growth so that relatively dust-free cones
with marginal conical dust surfaces and intervening zones highly
charged with dust resulted. In other cases nucleation occurred not
only on the carapace surface but on a number of thin semi-discrete
clay lenses, and growth proceeded from each, separating and forcing
them into a complex cone-in-cone structure (Bright, 1959, pi. 18,
fig. 2). In this way the complex cone-in-cone was produced on both
the dorsal and ventral surfaces of the specimen from Montana
(G-3569, fig. 70). The relatively complex coned veins from Cun-

Fig. 87. Diagrams illustrating origin of cone-in-cone lens related to original
sediment differences: a, initial conditions showing lenses of clay; b, cone-in-cone
formed during early diagenesis in clay lens.

294

Fig. 88. Diagrams illustrating origin of cone-in-cone in clay layers as a result
of compaction by overlying sediment during early diagenesis: a, initial develop-
ment of structureless concretion; b, development of cone-in-cone layers around
structureless core due to compaction of the clay. (.Only one coned layer may
develop.)

295

296 FIELDIANA: GEOLOGY, VOLUME 13

ningham Brook, New Brunswick, indicate more or less simultaneous
nucleation on discrete clay lenses ; in some cases this occurred on the
lower, sometimes on the upper, and sometimes on both surfaces,
producing cones with their apices directed both upward and down-
ward. In the complex but typical cone-in-cone specimens such as
those from Woodland Valley and Dotson's Branch, Indiana, the
same principles apply, but the cones in such layers all point in the
same direction (upward in these examples) save for a rare exception
(fig. 35). Why the growth should be consistently in one direction
is difficult to say unless it is related to the direction and mode of
supply of the ions, particularly in the very early stage of nucleation.

The cone-in-cone lenses in the sandstone specimens (G-3572-74,
p. 263) represent a special case. The growth of calcite in the inter-
stices of a relatively coarse sediment such as sand is not able to pro-
duce the cone-in-cone structure, as the fundamental conditions are
absent; a calcareous, cemented sandstone results, which is analogous
to a non-coned claystone concretion. But crystallization in clay
lenses (and possibly in fine silt lenses) within a sandstone will result
in cone-in-cone lenses identical to normal cone-in-cone except that
sparse sand grains are included within the crystalline structure.

5. How much expansion over the original thickness of sediment is
involved? Estimation of the amount of expansion involved in the
development of cone-in-cone structure is fraught with difficulties be-
cause the volume of the sediment at the commencement of crystal-
lization is not known nor is the effect of subsequent compaction by
the overlying beds. This latter effect must be slight in the case of
the cone-in-cone layer because of its crystalline nature. Morawietz
(1961) considers that there is little increase, and that this is restricted
to the upper layer of the double cone-in-cone layers. However, the
coned veins from Cunningham Brook, New Brunswick, the coned
concretions associated with trilobites and with the fossil fish, de-
scribed by Brown (1954), and the cone-in-cone separating the am-
monite impressions, described by Lang (Lang, et al., 1923), all point
decisively to a substantial increase of volume produced by the growth

Fig. 89. Diagrams illustrating origin of cone-in-cone in clay layers as a result
of compaction by growing concretion during early diagenesis: a, initial develop-
ment of structureless concretion; b, growth of concretion showing clay layers com-
pacted around it; c, further calcite deposited as fibrous coned layers around struc-
tureless core.

297

298 FIELDIANA: GEOLOGY, VOLUME 13

of calcite. With regard to the typical complex cone-in-cone no good
direct evidence is available. If the view is valid that the mud had
already been somewhat compacted at the time of crystallization,
then there must have been expansion, since it is unlikely that there
could have been zones of watery mud existing among layers and
lenses of partly compacted mud. Likewise, the lenses of cone-in-
cone occurring within the calcareous sandstone must represent con-
siderable expansion, as a lens of watery mud could not have existed
within sand. On the other hand, the presence of the brachiopod spine
descending along a macrocone clay layer (fig. 45) would suggest that
virtually no movement took place, although this is by no means cer-
tain, since the growth of the fine-grained calcite could have produced
a movement so delicate as not to disrupt the spine.

The structureless non-coned central portion of coned concretions
contains a notable proportion of clay; e.g., the insoluble residue of a
sample from the central zone of the Cape Breton Island specimen
(G-3586) is 28.4 per cent in comparison with 17.4 per cent of a sam-
ple from the upper coned layer. This indicates a greater addition
of calcite in the latter zone, where the calcite is coarser-grained and
most of the clay is separated into the conical layers. It is possible
that expansion is slight during the formation of early diagenetic
non-coned concretions. But, if the conditions pass transitionally
into those favoring the fibrous crystallization and development of
microcones, relative expansion increases and continues to do so as
the calcite coarsens and macrocones are formed; that is, the calcite
crystallization sets up increasing compaction in the sediment sur-
rounding the growing concretion. It is also likely that the clay layers
suffer further compaction as they become imprisoned between the
crystallized calcite of the conic scales.

6. What, if any, is the influence of the vertical pressure of over-
lying beds and what is the influence of the crystallizing force of calcite?
Neither the force of crystallization nor the weight of overlying beds
is responsible for inducing the cone structure in an already exist-
ing material. The crystallization force probably is partly respon-
sible for producing the physical state in the clay favorable for the
development of cone-in-cone. Similarly, the weight of overlying
sediment may operate in the same way and, although this differen-
tial pressure is slight, it may be sufficient to influence the growth
orientation of the calcite, producing fibers elongated parallel to the
"c" axes and more or less parallel to this force.

WOODLAND: CONE-IN-CONE STRUCTURE 299

7. What controls the size of cones, the size of the conical angles,
and the individualization of the cones? The cone angle and the size
of the cones are controlled by the physical properties of the sediment
— e.g., the degree of compaction and lamination of the clay — and by
the density of nucleation and rate of growth of the calcite which con-
trol the grain size. The microcones arise directly from the mode of
growth of individual fibre groups, which develop as tuft-like aggre-
gates from a nucleation point, the microcone apex. These groups
grow together and form the micro-fabric which, because of the fine
clay particles trapped between the grains and tufts, shows the char-
acteristic interfering microcones. Macrocones are established by
layers or lenses of clay that remain coherent and are forcibly de-
formed by the crystallizing calcite. The layers are forced into par-
tially conical surfaces by the differential development of the rela-
tively pure calcite of the microcones crystallizing between the layers.
The calcite forms the conic scales, which are separated by the corru-
gated or step-like clay layers. The number, degree of perfection,
and size of the conic scales are thus determined by the number and
thickness of the coherent clay lenses. Conic scales commonly thicken
toward the base of the cones and this may account, in part, for the
flaring of the cone angle toward the distal end. Coarsening of grain
toward the cone bases may be one cause of the increase in thickness
of conic scales. The apical angle of the macroscopic cones would
seem to be controlled by the cone-angle of the microcones. Random
packing of the similarly oriented microcones could result in partial
macrocones, the individualization of which is a function of the spac-
ing and number of the clay lenses. It may be, however, that the
stress state existing in the environment of crystallization controls
not only the lattice orientation of the fibrous calcite but also the
differential growth of the calcite that produces the macrocones; for
example, the growth may be influenced by cylindrical zones of vary-
ing rates of calcite deposition concentric to random axes which be-
come the eventual macrocone axes. (Concentric cylindrical zones
which increase in length toward the exterior produce an internal
cone-cup surface.) If the cone axes are parallel to the direction of
maximum stress, cylindrical zones around the axes will parallel poten-
tial tensional surfaces. Orientation of macrocones around a common
axis, as in specimens G-3586 and G-3587, arises from a control of the
axial position determined by original differences in the clay medium
at the time of initiation of crystallization (p. 233). The clay lenses
are commonly thicker toward the surface of the cone-in-cone marked

300 FIELDIANA: GEOLOGY, VOLUME 13

by the cone bases; this is possibly a result of a greater degree of
compaction.

8. What causes the cessation of growth? Growth of the cone-in-
cone layer naturally would cease if the supply of carbonate should
fail or if the physico-chemical conditions should become unfavorable
for continued deposition. Cone-in-cone development would also
come to an end if the correct physical clay environment were no
longer available. Deposition of calcite could continue but no cones
would result. An example of such a case is the cone-in-cone lenses in
sandstone, G-3572-74. The basal surface of a cone-in-cone layer is
generally an even one except for the irregularities formed by the arcs
of partial clay cones. Such evenness of development is also charac-
teristic of the coned trilobite concretions. This suggests that the
differential growth which produces the macroconing in complex cone-
in-cone layers is a relative effect; the overall thickness remains re-
markably constant (or diminishes in a regular way in the case of the
coned concretions whose coned layers taper out laterally), but what
has varied is the amount of nucleation and growth between the vari-
ous clay lenses and layers making up the total thickness.

Although cone-in-cone structure is widely distributed geographi-
cally in many formations of different ages, it is not of universal occur-
rence nor is it present in all argillaceous limestones by any means.
The reason for its restricted appearance is the necessity for a com-
bination of special circumstances, particularly the physical state of
the clay at the time concretionary action is taking place.

REFERENCES

Alcock, F. J.

1935. Geology of Chaleur Bay region. Canada, Dept. of Mines, Geol. Surv.,
Mem., 183, 146 pp.

Ashley, G. H.

1899. The coal deposits of Indiana. Indiana Dept. Geol. Nat. Res., 23rd Ann.
Rept. (for 1898), 1573 pp.

BONTE, A.

1942. Sur 1'origine sedimentaire de la structure cone-in-cone. Acad, des Sci.,

C. R., 214, pp. 498-500.
1945a. Observations sur les nodules a structure cone-in-cone de l'Arenig de la

Montagne Noire. Soc. Geol. de France, Bull., ser. V, 15, pp. 453-478.
1945b. Sur les gradins concentriques propres a la structure cone-in-cone. Acad.

des Sci., C. R., 221, pp. 507-509.
1952. Reflexions sur le "beef," a propos d'une note de M. L. David. Soc. Geol.

de France, C. R., no. 7, pp. 110-112.

Bonte, A., Denaeyer, M. E., and Goguel, J.

1947. Les facteurs mecaniques dans la genese de la structure "cone-in-cone."
Soc. Geol. de France, C. R., no. 9, pp. 182-184.

Boyd, D. W., and Ore, H. T.

1963. Patterned cones in Permo-Triassic redbeds of Wyoming and adjacent
areas. Jour. Sed. Pet., 33, pp. 438-451.

Bright, R. C.

1959. A paleoecologic and biometric study of the Middle Cambrian trilobite
Elrathia kingii (Meek). Jour. Paleo., 33, pp. 83-98.

Brown, R. W.

1954. How does cone-in-cone material become emplaced? Amer. Jour. Sci.,
252, pp. 372-376.

Bucher, W. H.

1963. Cryptoexplosion structures caused from without or from within the
Earth? ("Astroblemes" or "Geoblemes.") Amer. Jour. Sci., 261, pp. 597-649.

Cayeux, L.

1935. Les roches sedimentaire de France, Roches carbonatees. 463 pp. Masson
et Cie, Paris.

Cole, G. A. J.

1893. On some examples of cone-in-cone. Min. Mag., 10, pp. 136-141.

David, L.

1952. Presence de la structure "beef" et "cone-in-cone" dans le Cretace de
l'Est-Constantinois (Algerie). Soc. Geol. de France, C. R., no. 3, pp. 51-52.

Dawson, J. W.

1868. Acadian Geology. 2nd ed., 694 pp. MacMillan and Co., London.

301

302 FIELDIANA: GEOLOGY, VOLUME 13

Denaeyer, M. E.

1939. La reproduction experimental de la structure cone-in-cone. Ses con-
sequences au point de vue de la tectonique. Acad, des Sci., C. R., 208,

pp. 2004-2006.
1940a. Sur la microstructure et la composition des "cone-in-cone" du Siegenien

metamorphique de Morhet (Ardennes beiges). Soc. beige de Geol., de Paleo.,

et d'Hydro., Bull., 49, pp. 119-125.
1940b. Resultats d'experience relative a la genese de la structure "cone-in-cone."

Soc. beige de Geol., de Paleo., et d'Hydro., Bull., 49, pp. 313-318.
1940c. Les schists arenigiens a structure "cone-in-cone" de la tranchee de Sart-

Bernard (province de Namur). Soc. beige de Geol., de Paleo., et d'Hydro.,

Bull., 49, pp. 318-326.

1945. Essai d'une theorie mecanique de la structure cone-in-cone. Soc. Geol.
de France, Bull., ser. V, 15, pp. 141-160.

1946. Sur les cone-in-cone et les septaria. Acad, des Sci., C. R., 223, pp. 953-
954.

1947. Les gisements de cone-in-cone de France et de Grand Bretagne. Soc. beige
de Geol., de Paleo., et d'Hydro., Bull., 56, pt. 1, pp. 21-46; pt. 2, pp. 382-411.

1952. Sur la signification des "filons" transversaux a structure "beef" et "cone-
in-cone." Soc. Geol. de France, C. R., no. 8, pp. 138-140.

1954. Sur l'existence de "filons" de calcite a structure "beef" et "cone-in-cone."
Conclusions au point de vue genetique. XIX Congr. Geol. Intern. Alger 1952,
C. R., sec. XIII, fasc. XV, pp. 387-396.

Dietz, R. S.

1959. Shatter cones in cryptoexplosion structures (meteorite impact?). Jour.
Geol., 67, pp. 496-505.

1960. Meteorite impact suggested by shatter cones in rock. Science, 131,
pp. 1781-1784.

1961. Astroblemes. Sci. Amer., 205, pp. 50-58.

1963. Cryptoexplosion structures: A discussion. Amer. Jour. Sci., 261 , pp. 650-
664.

Folk, R. L.

1962. Petrography and origin of the Silurian Rochester and McKenzie shales,
Morgan County, West Virginia. Jour. Sed. Pet., 32, pp. 539-578.

Gage, M., and Bartrum, J. A.

1942. Cone-in-cone and ring-fracture in coal from Greymouth, New Zealand.
New Zealand Jour. Sci. and Tech., 24, B. General Section, pp. 86B-98B.

Gay, R.

1942. Theorie de la formation de la structure cone-in-cone. Acad, des Sci.,
C. R., 214, pp. 500-502.

Gresley, W. S.

1894. Cone-in-cone: How it occurs in the Devonian Series in Pennsylvania,
U.S.A., with further details of its structure, varieties, etc. Geol. Soc. London,
Quart. Jour., 50, pp. 731-739.

Griggs, D. T., Turner, F. G., and Heard, H. C.

1960. Deformation of rocks at 500° to 800° C. Geol. Soc. America, Mem., 79,
pp. 39-104.

Grout, F. F.

1946. Microscopic characters of vein carbonates. Econ. Geol., 41, pp. 475-502.

Harnly, H. J.

1898. "Cone-in-cone" (an impure calcite). Kansas Acad. Sci., Trans., 15, p. 22.

WOODLAND: CONE-IN-CONE STRUCTURE 303

Harrington, H. J., and Leanza, A. F.

1957. Ordovician trilobites of Argentina. Univ. Kansas, Dept. Geol., Spec.
Publ. 1, 276 pp.

Hendricks, T. A.

1937. Some unusual specimens of cone-in-cone in manganiferous siderite. Amer.
Jour. Sci., ser. 5, 33, pp. 458-461.

Herrmann, R.

1930. Tutenmergel und Nagelkalk. Leopoldina (Walther-Festschrift), 6,
pp. 125-158.

Honess, C. W.

1923. Geology of the southern Ouachita Mountains of Oklahoma: Part I. Stra-
tigraphy, structure and physiographic history. Oklahoma Geol. Surv., Bull.,
32, 278 pp.

Kamb, W. B.

1959. Theory of preferred crystal orientation developed by crystallization under
stress. Jour. Geol., 67, pp. 153-170.

Keyes, C. R.

1896. Note on the nature of cone-in-cone. Iowa Acad. Sci., Proa, 3, pp. 75-76.

Lalou, C.

1957. Studies on bacterial precipitation of carbonates in sea water. Jour. Sed.
Pet., 27, pp. 190-195.

Lang, W. D., Spath, L. F., and Richardson, W. A.

1923. Shales-with-Beef, a sequence in the Lower Lias of the Dorset coast.
Geol. Soc. London, Quart. Jour., 79, pp. 47-98.

Lhoest, A.

1962. A propos de structures "cone-in-cone" dans les charbons. Soc. beige de
Geol., de Paleo., et d'Hydro., Bull., 71, pp. 146-148.

Linck, G.

1930. Tutenmergel und Nagelkalk. Chemie der Erde, 6, pp. 227-238.

Linck, G., and Noll, W.

1928. Uber Tutenmergel. Chemie der Erde, 3, pp. 699-721.

Mackenzie, G. S.

1951. Preliminary map, Hampstead, Queens, Kings, and Sunbury Co., New
Brunswick. Geol. Surv. Canada, Paper 51-19.

Marsh, O. C.

1868. On the origin of the so-called lignilites or epsomites. Amer. Assoc.
Adv. Sci., Proa, 16, pp. 135-143.

Morawietz, F. H.

1961. Zur Genese des Nagelkalkes. Neues Jahrb. Geol. und Pal., 112, pp. 229-
249.

MULLER, A. H.

1962. Fossil oder Pseudofossil? Geologie, Jahrg. 11, pp. 1204-1213.

Mykura, W.

1960. The replacement of coal by limestone and the reddening of coal measures
in the Ayrshire coalfield. Gt. Brit., Geol. Surv., Bull., 16, pp. 69-106.

304 FIELDIANA: GEOLOGY, VOLUME 13

Noll, W.

1931. Uber Nagelkalke und neuartige Kegelbildungen aus dem Thuringer Un-
terkeuper. Zbl. Min., A, pp. 169-181.

Pantin, H. M.

1958. Rate of formation of a diagenetic calcareous concretion. Jour. Sed. Pet.,
28, pp. 366-371.

Pettijohn, F. J.

1957. Sedimentary rocks. 2nd ed., 718 pp. Harper & Bros., New York.

Reis, 0. M.

1903. Ueber Stylolithen, Dutenmergel und Landschaftenkalk (Anthrakolith

zum Theil). Geog. Jahresh. Kgl. bayr. Oberbergamt in Miinchen, 1902,

pp. 157-279.
1914. Zur Frage der Entstehung von Konkretionen. Geog. Jahresh. Kgl. bayr

Oberbergamt in Miinchen, 1913, pp. 281-290.

Richardson, W. A.
1923. See Lang, W. D., Spath, L. F., and Richardson, W. A.

Schone-Warnefeld, G., and Dahm, H.

1962. Tutenmergel im Ruhrkarbon. Fortschr. Geol. Rheinl. u. Westf., 3,
pt. 2, pp. 643-646.

Shaub, B. M.

1937. The origin of cone-in-cone and its bearing on the origin of concretions
and septaria. Amer. Jour. Sci., ser. 5, 34, pp. 331-344.

Shoemaker, E. M., Gault, D. E., and Lugn, R. V.

1961. Shatter cones formed by high speed impact in dolomite. U. S. Geol.
Surv., Prof. Paper 424 D., pp. 365-368.

Sorby, H. C.

1860. On the origin of "cone-in-cone." British Assoc. Adv. Sci., report of
29th meeting, 1859, Trans, of Sections, Geology, p. 124.

Steinmann, G., and Hock, H.

1912. Das Silur und Cambrium des Hochlandes von Bolivia und ihre Fauna.
Neues Jahrb. Mineral., Geol. und Pal., Beil. B, 34, pp. 176-252.

Stubblefield, C. J.

1930. A new Upper Cambrian section in South Shropshire. Gt. Brit., Geol.
Surv., Summary of Progress 1929, Part II, pp. 55-62.

T ANTON, T. L.

1931. Fort William and Port Arthur, and Thunder Cape map-areas, Thunder
Bay District, Ontario. Canada, Geol. Surv., Mem., 167.

Tarr, W. A.

1922. Cone-in-cone. Amer. Jour. Sci., ser. 5, 4, pp. 199-213.

1932. Cone-in-cone. In Twenhofel, W. H., Treatise on sedimentation. Wil-
liams and Wilkins Co., Baltimore. 2nd ed., pp. 716-733.

Thoral, M.

1942. A propos de la structure cone in cone. Soc. Geol. de France, C. R.,
no. 13, pp. 144-146.

1946. Cycles g^ologiques et formations noduliferes de la Montagne Noire.
Nouv. Arch. Mus. d'Hist. Nat. de Lyon, pt. 1, 103 pp.

WOODLAND: CONE-IN-CONE STRUCTURE 305

Turner, F. J.

1949. Preferred orientation of calcite in Yule marble. Amer. Jour. Sci., 247,
pp. 593-621.

TWENHOFEL, W. H.

1950. Principles of sedimentation. 2nd ed., 673 pp. McGraw-Hill Book Co.,
Inc., New York.

Weller, J. M.

1960. Stratigraphic principles and practice. 725 pp. Harper & Bros., New
York.

Zangerl, R., and Richardson, E. S., Jr.

1963. The paleoecological history of two Pennsylvanian black shales. Fieldi-
ana, Geol. Mem., 4, 352 pp.

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