c a 
 
 G^tA S^svjlx-^ 
 
 STATE OF ILLINOIS 
 
 WILLIAM G. STRATTON, Governor 
 
 DEPARTMENT OF REGISTRATION AND EDUCATION 
 
 VERA M. BINKS, Director 
 
 PETROGRAPHY AND ORIGIN 
 OF ILLINOIS NODULAR CHERTS 
 
 Donald L. Biggs 
 
 DIVISION OF THE 
 
 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 JOHN C. FRYE, Chief URBANA 
 
 CIRCULAR 245 
 
 ILLINOIS GEOLOGICAL 
 SURVEY LIBRARY 
 JAN 9 1958 
 
 1957 
 
ILLINOIS STATE GEOLOGICAL SURVEY 
 
 3 3051 00004 4572 
 
PETROGRAPHY AND ORIGIN OF 
 ILLINOIS NODULAR CHERTS 
 
 Donald L. Biggs 
 
 ABSTRACT 
 
 Seventy-eight samples of nodular chert from 18 Illinois lime- 
 stone and dolomite formations, ranging from Cambrian through 
 Mississippian age, were investigated todetermine the petrography 
 and mode of origin of the nodules. Regardless of geologic age or 
 type of host rock, the nodules were similar in mode of occurrence 
 and in principal textural characteristics. 
 
 The cherts are dominantly microcrystalline or cryptocrys- 
 talline quartz with a lesser amount of fibrous quartz. No opal or 
 hydrated silica was detected. Almost all the cherts contain re- 
 sidual masses of their host rock. Field relationships and a varie- 
 ty of evidence for replacement leads to the conclusion that the 
 cherts are epigenetic concretions formed by metasomatic proc- 
 esses operating during diagenesis and involving the aggregation of 
 silica that originally had been deposited syngenetically with, and 
 dispersed through, the host rocks. 
 
 INTRODUCTION 
 
 Chert is found in many limestones that crop out in Illinois and range in 
 age from Cambrian to Mississippian. The chert may appear as nodules, len- 
 ses, or beds, and some Devonian rocks in extreme southern Illinois are entire- 
 ly chert. 
 
 The investigation reported here was limited to a study of the nodular 
 cherts and deals with the petrography and mode of origin of the nodules. 
 
 Grateful acknowledgment is made of assistance received in this investi- 
 gation from D. L. Graf and J. E. Lamar of the Illinois State Geological Survey 
 and Carleton A. Chapman of the University of Illinois. 
 
 SAMPLES 
 
 Chert samples were obtained from 35 outcrops whose geological identi- 
 ty and number of outcrops sampled are given below: 
 
 Mississippian System: Kinkaid limestone (1); Vienna limestone (1); Ste. 
 Genevieve limestone (2); St. Louis limestone (4); Salem limestone (3); Burling- 
 ton limestone (4). 
 
 Devonian System: Clear Creek chert (1); Backbone limestone (1); Bailey 
 limestone (2). 
 
 Silurian System: Racine dolomite (1); Kankakee dolomite (2); Sexton 
 Creek limestone (2); Girardeau limestone (1). 
 
 Ordovician System: Galena dolomite through Platteville dolomite (1); 
 Shakopee dolomite (2); Oneota dolomite (2). 
 
 Cambrian System: Trempealeau dolomite (1). 
 
 [1] 
 
2 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 The outcrops were sampled by taking several nodules of chert from each 
 conspicuous zone or type of chert present. The samples were marked so that 
 thin sections could be cut normal to the bedding. 
 
 OCCURRENCE AND COLOR OF CHERT NODULES 
 
 Chert nodules in Illinois limestones and dolomites generally are less 
 than three feet in diameter and are commonly more or less flattened parallel 
 to their horizontal axes and to the bedding of the enclosing rock. Nodules of 
 almost perfect spherical shape have been observed but are rare. All nodules 
 have a megascopically smooth, though commonly irregular, outline. Knobs 
 and other types of protuberances are common. The contact of the nodules with 
 the enclosing rock is in all cases smoothly curving. Some nodules have a 
 knife -sharp contact, in others the contact is diffuse or transitional. 
 
 Oolites, bedding, and other structures that are common in the surround- 
 ing limestone or dolomite are observed in many chert nodules. In some places 
 in extreme southern Illinois, nodules contain small crystals and thin veins of 
 fluorspar that cross linear structures in the chert without offset and terminate 
 at the boundary of the nodules. 
 
 The nodules in Illinois limestones and dolomites do not appear to be as- 
 sociated with a solution channel network or with specific bedding planes. The 
 chert is randomly distributed at most exposures. The nodules are restricted 
 to certain zones in some formations, but within the zones they do not occur at 
 any particular horizon. Where nodules are concentrated in a particular zone 
 they are commonly smaller than at nearby localities where they are farther 
 apart. 
 
 The cherts sampled were black, brown, gray, blue, and white (discount- 
 ing surface staining due to weathering). Chert of the Kinkaid, Ste. Genevieve, 
 and St. Louis limestones generally was dark gray to black; light brown, light 
 gray, and white cherts predominate in the Salem, Burlington, Clear Creek, 
 Backbone, Bailey, Racine, Kankakee, Sexton Creek, Galena, Platteville, Shako- 
 pee, Oneota, and Trempealeau formations. Dark brown chert was found only 
 in the Girardeau and Vienna limestones, and one sample from the Vienna for- 
 mation was light blue. 
 
 METHODS OF LABORATORY STUDY 
 
 All chert samples were studied by means of thin sections. Seventeen 
 samples were further studied by infrared absorption and eleven by x-ray dif- 
 fraction to check on the accuracy of thin-section determinations and to inves- 
 tigate the possible occurrence of opal and amorphous silica. 
 
 All samples investigated by infrared absorption contain quartz, eleven 
 calcite, and twelve dolomite. Six samples contain both calcite and dolomite; 
 of the remaining eleven, six cherts contain dolomite as the only carbonate 
 whereas five have calcite but no dolomite. 
 
 Quartz is present in all eleven cherts examined by x-ray diffraction. 
 Calcite is present in ten of the cherts, whereas dolomite is present in eight. 
 The only chert that has no calcite contains dolomite. 
 
ILLINOIS NODULAR CHERTS 3 
 
 X-ray and infrared absorption data for the cherts examined by both meth- 
 ods are in agreement. All the cherts contain carbonate minerals. Quartz is 
 the most abundant and essential mineral in the nodules. None of the cherts 
 examined contain opal or amorphous silica. 
 
 PETROGRAPHY 
 
 The character of the cherts as shown in thin sections is indicated in 
 table 1 and summarized in table 2. No consistent differences related to geo- 
 logic age are evident. The quartz in cherts from dolomites is somewhat finer 
 grained than that in limestone cherts, but not distinctively so. 
 
 More fossils and coquina or coquinoid material is found in cherts from 
 limestones than in dolomite cherts, which is to be expected because Illinois 
 limestones contain more fossils and fossil materials than do Illinois dolomites. 
 Because of the general similarity of the cherts, their character and origin is 
 discussed without reference to formation or kind of host rock. 
 
 Quartz 
 
 Thin-section examination of the cherts shows that their essential and 
 most abundant mineral is quartz. The quartz occurs in three varieties, micro- 
 crystalline (crystals less than 0.1 but greater than 0.01 mm. in diameter), 
 cryptocrystalline (less than 0.01 but greater than 0.002 mm. in diameter), and 
 fibrous quartz, sometimes called chalcedony. Some specimens show quartz 
 euhedra. The length of fibers in the fibrous quartz is highly variable, depend- 
 ing upon the width of separation of centers of crystallization. 
 
 The terms microcrystalline and cryptocrystalline quartz have been here 
 adopted for convenience in textural classification of the cherts. The two types, 
 which differ only in grain size, make up more than 95 percent of the silica con- 
 tent of the chert. 
 
 Keller (1941), using the term microcrystalline quartz to include the ma- 
 terial for which both terms mentioned above have been used, showed that the 
 fine-grained silica has the optical and x-ray properties of quartz, except that 
 the extinction is undulatory. He attributed the undulatory extinction to strain- 
 ing of the quartz developed in transition from colloidal silica to microcrys- 
 talline quartz. There seems little evidence that the quartz crystals are great- 
 ly strained. It is known that if crystals are smaller than the thickness of the 
 section, undulatory extinction results from the passage of light through several 
 misorientated crystals. 
 
 It appears that such small quartz crystals grow by replacing carbonate 
 minerals. Individual crystals of carbonate are found that have microcrystalline 
 and cryptocrystalline quartz traversing them, outlining crystal rims, or grow- 
 ing in irregular masses within them. 
 
 The microcrystalline quartz commonly is clouded by opaque dust. This 
 dust may be iron, carbonaceous matter, or other impurities that could be ac- 
 cepted and hidden in the structure of the carbonate minerals but that finds no 
 place in quartz and so forms an oxide or other phase, either crystalline or 
 amorphous, that is less subject to replacement by the quartz. Some darkening 
 of the quartz is due to finely disseminated carbonate material that has not been 
 
ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Table 1. - Texture of Chert 
 
 Formation 
 
 
 Te 
 
 xture 
 
 of chert 
 
 
 Evidences of replacement 
 
 and 
 
 
 
 
 
 
 
 
 kind of 
 
 
 
 
 
 
 
 
 rock 
 
 
 
 G 
 
 •rH 
 
 
 
 
 Pseudomorphs of 
 
 
 0) 
 
 0< 
 
 T) 
 
 
 r— 1 
 
 ni 
 
 H-> 
 
 
 n 
 
 quartz after 
 
 
 
 Primary rock 
 
 Is. = limestone 
 
 ni 
 6 
 
 2 
 
 Coquina 
 coquinoi 
 
 8-S 
 
 P-< n 
 
 c ° 
 u S 
 
 U 
 
 O o 
 ° 'm 
 
 .a s 
 
 u 
 
 ■rH 
 •H 
 
 o 
 O 
 
 
 
 o 
 
 0) 
 
 o 
 
 -rH 
 ■ — 1 
 ■rH 
 
 CO 
 
 Crystals 
 
 structures 
 
 dol.= dolomite 
 
 Unit 
 
 Aggre- 
 gates 
 
 Oolites 
 
 Fossils 
 
 Kinkaid Is. 
 Vienna Is. 
 
 Ste. Genevieve 
 oolite 
 
 St. Louis Is. 
 Warsaw-Salem Is. 
 
 Burlington Is. 
 Clear Creek Is. 
 
 Backbone Is. 
 Bailey Is. 
 
 Racine dol. 
 Kankakee dol. 
 
 Sexton Creek Is. 
 Girardeau Is. 
 
 Galena dol. 
 Platteville dol. 
 
 Shakopee dol. 
 Oneota dol. 
 
 Trempealeau dol. 1 
 
 1 
 
 - 
 
 - 
 
 1 
 
 3 
 
 1 
 
 1 
 
 1 
 
 13 
 
 4 
 
 3 
 
 5 
 
 10 
 
 1 
 
 1 
 
 7 
 
 4 
 
 2 
 
 2 
 
 - 
 
 13 
 
 7 
 
 2 
 
 4 
 
 2 
 
 - 
 
 - 
 
 2 
 
 3 
 
 _ 
 
 1 
 
 1 
 
 3 
 
 - 
 
 1 
 
 2 
 
 3 
 
 - 
 
 3 
 
 - 
 
 3 
 
 - 
 
 1 
 
 1 
 
 2 
 
 - 
 
 _ 
 
 2 
 
 1 
 
 - 
 
 1 
 
 - 
 
 5 
 
 _ 
 
 4 
 
 1 
 
 ] 
 
 - 
 
 1 
 
 - 
 
 6 
 
 - 
 
 _ 
 
 - 
 
 4 
 
 _ 
 
 1 
 
 1 
 
 - 
 
 - 
 
 1 
 
 - 
 
 - 
 
 3 
 
 - 
 
 1 
 
 13 
 
 1 
 
 1 
 
 10 
 
 - 
 
 - 
 
 4 
 
 - 
 
 - 
 
 12 
 
 - 
 
 2 
 
 2 
 
 1 
 
 1 
 
 3 
 
 - 
 
 2 
 
 3 
 
 - 
 
 1 
 
 3 
 
 1 
 
 1 
 
 3 
 
 _ 
 
 - 
 
 2 
 
 - 
 
 - 
 
 1 
 
 _ 
 
 _ 
 
 5 
 
 - 
 
 - 
 
 1 
 
 4 
 
 5 
 
 6 
 
 2 
 
 _ 
 
 3 
 
 1 
 
 3 
 
 12 
 
 9 
 4 
 
 12 
 1 
 
 3 
 
 1 
 
 3 
 1 
 
 1 
 
 1 
 
 * Not strictly textural but included here for convenience. 
 
 t The numbers indicate the number of specimens showing a given phenomenon. 
 
ILLINOIS NODULAR CHERTS 
 
 and Evidences of Replacement! 
 
 
 
 
 
 
 
 
 E 
 
 vidences of replacement 
 
 
 
 
 
 e * 
 
 
 
 
 
 «j m 
 
 
 
 (0 
 
 
 
 
 10 
 
 
 
 10 2 
 
 
 Xl 
 
 X 
 
 U -M 
 
 
 co 
 
 
 
 ■M JZ 
 
 
 - 
 
 u 
 
 nj <d 
 
 |* 
 
 >> 
 
 
 
 U ' 
 
 a) 
 u 
 c 
 
 nj 
 
 
 3 O 
 
 111 
 
 h 
 
 
 Miscellaneous 
 
 C o 
 
 (0 
 
 [J 
 
 -r-t 
 
 CT 1 ,3 
 
 3 
 
 o 
 
 
 
 O n 
 
 •a <u 
 
 X5 S 
 
 a> 
 
 X 
 o 
 
 M 
 
 •4-> 
 
 O 4-> 
 
 05 3 
 
 s -° 
 
 M-l 
 
 o 
 o 
 
 a) 
 
 3 
 o 
 
 J3 
 
 
 
 E u 
 
 w o 
 
 o 
 
 4) 
 
 o 
 
 01 d 
 M U 
 
 u 
 
 
 O 
 
 
 
 1 
 
 - 
 
 1 
 
 1 
 
 3 
 
 3 
 
 - 
 
 3 
 
 11 
 
 10 
 
 9 
 
 8 
 
 8 
 
 5 
 
 4 
 
 5 
 
 1 
 
 - 
 
 - 
 
 3 
 
 11 
 
 8 
 
 7 
 
 3 
 
 2 
 
 1 
 
 1 
 
 1 
 
 3 
 
 2 
 
 2 
 
 1 
 
 3 
 
 2 
 
 2 
 
 2 
 
 2 
 
 - 
 
 2 
 
 _ 
 
 3 
 
 3 
 
 2 
 
 - 
 
 2 
 
 1 
 
 _ 
 
 1 
 
 1 
 
 - 
 
 - 
 
 1 
 
 3 
 
 3 
 
 3 
 
 1 
 
 4 
 
 2 
 
 5 
 
 2 
 
 1 
 
 1 
 
 1 
 
 _ 
 
 Relict bedding - 1 
 
 Relict bedding - 1 
 Relict limestone texture 
 
 Pelitic - 2 
 
 Much carbonate - 2; relict bedding - 1 
 
 Much dolomite - 1 
 Relict bedding - 2 
 
 Relict bedding - 1 
 
 Large masses of dolomite - 2 
 Large masses of dolomite - 1 
 
 Detrital quartz - 4 
 Relict bedding - 1 
 
ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Table 2. - Summary of Data in Table 1 by Host Rock Types 
 
 Texture of chert 
 
 Coquina or coquinoid 
 Cryptocrystalline mosaic 
 Microcrystalline mosaic 
 Oolitic 
 
 Evidence of replacement 
 
 Pseudomorphs of quartz after: 
 Unit crystals 
 Aggregates of crystals 
 Oolites 
 Fossils 
 Embayed crystals or masses of host 
 
 rock in chert 
 Residual islands of host rock in 
 
 chert 
 Islands of quartz in host rock 
 Growth of new carbonate crystals 
 
 Frequency (%) 
 Limestone Dolomite 
 
 27 
 
 
 
 22 
 
 43 
 
 45 
 
 13 
 
 9 
 
 4 
 
 13 
 
 13 
 
 98 
 
 96 
 
 9 
 
 13 
 
 69 
 
 43 
 
 84 
 
 61 
 
 58 
 
 43 
 
 47 
 
 61 
 
 53 
 
 13 
 
 replaced. Thin sections of some cherts display no carbonate matter but are 
 clouded by a brown film. X-ray studies of these same cherts show the pres- 
 ence of a carbonate that is in many cases dolomite. 
 
 In some of the carbonate -clouded thin sections, replacement veins of 
 calcite have developed. Around the veins the slide is clear in plane polarized 
 light. In polarized, analyzed light, however, the quartz crystals show up as 
 the usual steel gray mosaic. Farther away from the vein, the quartz is cloudy 
 and brown. It appears that the calcite vein has served as a depository for the 
 brownish carbonate material removed from the cleared area. 
 
 Fibrous quartz of the variety often called chalcedony is subordinate to 
 the other kinds of quartz in the cherts. It normally comprises less than three 
 percent of the quartz present in any nodule. Folk and Weaver (1952) observed 
 that chalcedony was restricted to sites where a free surface was present for 
 its nucleation. Their observation is confirmed in the cherts studied for this 
 report. Fibrous quartz is found in vugs, fissures, and inside of fossils or 
 other minute openings in the rock, but was not observed to replace the carbon- 
 ate minerals as do microcrystalline and cryptocrystalline quartz. 
 
 Pelto (1956) has shown that chalcedony consists of quartz crystallites 
 oriented with their C-axes normal to the length of the fibers. Crystallite C- 
 axes do not lie in a common plane; rather, they tend to rotate about the fibers, 
 which are not perfectly straight. The structural misfit between crystallites 
 is accommodated by elastic straining of the quartz structure on either side of 
 the misfit boundary in the event of small angle deviations. Where the angular 
 divergence is large, the misfit is accommodated by dislocations between the 
 
ILLINOIS NODULAR CHERTS 7 
 
 quartz crystallites and by less elastic straining. Instances of large -angle 
 misfit (greater than about 20°) are characterized by dislocations increasing 
 in number as the angle increases. Mis orientations of very large angle may 
 have dislocations so closely spaced that the material takes on the character 
 of a liquid. 
 
 In view of Pelto's discussion there seems no justification for the use 
 of the term "chalcedony," so "fibrous quartz" is used here as a term that is 
 at once more descriptive of the material and less likely to lead to confusion. 
 The properties of fibrous quartz that differ from those of macroscopic quartz 
 crystals are probably due to the poor organization and the adsorption of ions 
 in the zones of bad fit. 
 
 The fibrous quartz in Illinois cherts developed in openings, generally 
 small, and the initial deposits consisted of very short fibers extending perpen- 
 dicularly from many closely spaced sites of nucleation on the walls of the open- 
 ings. Successive groups of fibrous crystals grew on the free ends of preced- 
 ing crystals to form rough zones or bands, and in each new group the nuclei 
 were wider and the fibers longer than in preceding zones. This continued un- 
 til the openings were filled or crystals for some reason ceased to form. Some 
 of the zones are brown, others clear; fibers in some zones have a positive 
 elongation, others a negative elongation. Some of these phenomena are shown 
 in plate 2, figure D. 
 
 The fibrous quartz in small openings commonly consists of a single 
 zone of fibers and shows the foregoing features less perfectly than does the 
 quartz in larger cavities. The number of zones is largely dependent upon the 
 size of the opening. The length of the fibers in successive .zones varies, but 
 in one large fracture filling the initial fibers were 5 to 1 microns long and 
 developed from centers of crystallization 3 to 5 microns apart. Successive 
 zones of fibers started from centers 10 to 20, 40 to 60, and 100 to 130 microns 
 apart and the fibers were respectively 8 to 10, 20 to 40, and 160 to 290 microns 
 long. 
 
 Carbonate Minerals 
 
 Carbonate minerals, either as individual crystals or host-rock masses, 
 occur in all thin sections studied. Many nodules found in limestone have a 
 zone of dolomite crystals near the chert-limestone interface. Although dolo- 
 mite is common in cherts from limestones, nodules from dolomite formations 
 contain little calcite. 
 
 Isolated masses of host rock, ranging from large polycrystalline frag- 
 ments down to individual crystals, are common in nodules from all formations 
 examined. These carbonate minerals have the same optical properties and, 
 subject to their retaining sufficient size to contain them, the same primary 
 structures and textures as the host rock. Moreover, structures are observed 
 that originally must have been calcite but are now in whole or in part composed 
 of quartz. This is particularly true of fossils. Fossils found in the chert, 
 whether contained within carbonate rock fragments and composed of carbonate 
 minerals or now completely quartz, are those characteristic of the formation. 
 
 Host-rock masses have been more or less embayed by the quartz. 
 Many large crystals have been embayed to such an extent that they appear 
 
8 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 surrounded by small islands in optical continuity with the main mass. The de- 
 gree of corrosion by quartz generally increases from the peripheral regions 
 to the center of the nodule. 
 
 Other isolated carbonate crystals within the chert and immediately on 
 the host-rock side of the chert-limestone contact have optical properties that 
 differ from the minerals of the host rock. These crystals, which are subhedral 
 to euhedral in outline, are called euhedral carbonates in this discussion. Ex- 
 amination with the universal stage*, using the technique described by Emmons 
 (1943), shows the euhedral carbonates to be dominantly dolomite with a few 
 crystals of ankeritic composition. 
 
 The euhedral carbonates in the chert are free of opaque impurities to 
 a much greater extent than are the host-rock minerals. They have never been 
 observed to contain fossil fragments, oolites, or any other primary rock 
 structures. They form sharp boundaries against both quartz and host-rock 
 carbonate crystals, truncating any primary structure present in either. Eu- 
 hedral carbonates seem to be attacked by quartz much more slowly than are 
 the carbonate crystals of the host rock. They persist as sharp euhedra until 
 zones deep within the nodule are reached where the host-rock carbonates have 
 been reduced to shred-like masses. A few euhedra in the central regions of 
 nodules show attack by the quartz in that the obtuse corners are corroded; the 
 rest of the crystals retain sharp outline. 
 
 Thin sections of the host rock a few inches away from the interface 
 show few euhdral carbonates. Beginning about one-half inch on the host-rock 
 side of the interface, carbonate euhedra become common and continue to in- 
 crease in abundance until a maximum concentration is reached at the inter- 
 face of host rock and chert interface. Skeletal crystals are common near the 
 chert and host-rock contact. Although found in both host rock and quartz, they 
 are more common in the former. Some skeletal euhedral carbonates disregard 
 crystal boundaries and incorporate portions of several crystals. Others are 
 compositionally zoned as shown in plate 2, figure F. Universal stage measure- 
 ments indicate that some of the zones are ankeritic and others dolomitic. 
 
 To summarize, the euhedral carbonates are marked by the following 
 characteristics. 1) They are rare or absent in the host rocks except near the 
 boundaries of chert nodules. 2) Their chemical composition differs from that 
 of the host rock. 3) Even in coquinoid or oolitic rocks, the euhedral rhombs 
 have not been observed to contain fossils or oolites. 4) They are always eu- 
 hedral to subhedral and form sharp boundaries against the matrix except where 
 corroded by quartz. 5) They are free of opaque impurities to a much greater 
 extent than are the host-rock minerals. 6) They truncate all primary rock 
 structures present. 
 
 These characteristics are evidence of an authigenic and epigenetic 
 origin of the euhedral carbonates. Had they formed at the time of deposition 
 the euhedral carbonates would not display truncation of primary structures, 
 they would hardly be restricted to the neighborhood of chert nodules, and more 
 subhedral to anhedral crystals would be expected. 
 
 Calcite occurs as fracture fillings in the cherts. Some of it may be 
 derived from the limestone outside the nodule, but much of it seems to have 
 been furnished by the carbonate minerals in the chert. The calcite is clear, 
 
ILLINOIS NODULAR CHERTS 9 
 
 free of opaque impurities, and occurs in large crystals. It truncates all other 
 phases present. The chert around such veins is generally free of any but 
 large crystals of carbonate minerals. Even the large masses are more cor- 
 roded than similar material farther away from the vein. 
 
 Other Minerals 
 
 In addition to quartz and the carbonate minerals described above, 
 fluorite and hydrous oxides of iron are present in some cherts as minor ac- 
 cessory minerals. A black material that is opaque but not metallic is ob- 
 served in some thin sections. It is thought to be organic matter because it is 
 most abundant in the more fossiliferous rocks. 
 
 Fluorite in cherts is limited in occurrence to the rocks near the fluo- 
 rite mining area in southern Illinois. It is present in the cherts as isolated 
 irregular bodies and as thin veins that replace the quartz preferentially leav- 
 ing carbonate minerals apparently untouched. The veins and metacrystals 
 are completely contained in the chert. They have not been observed to pass 
 into the limestone at any place. 
 
 Reddish bodies of hydrated iron oxide occur around included masses 
 of host rock in the chert as shown in plate 1, figure E, and in the host rock 
 near the margins of chert nodules. 
 
 Mineral Relationships 
 
 The oldest mineral in the cherts is the carbonate of the host rock. 
 Individual crystals, fossils, and masses of the host-rock carbonate have been 
 observed that were cut by quartz, dolomite euhedra, and calcite fracture fill- 
 ing. 
 
 The dolomite rhombs truncate all structures in the host rock and are 
 commonly found isolated in the quartz. They are in turn corroded by the 
 quartz in some instances. It seems likely that the euhedral carbonates 
 formed in and at the expense of the host-rock carbonates and were left in con- 
 tact with the quartz by reason of their greater stability when the host rock 
 was replaced by the quartz. Quartz truncates both host-rock carbonate 
 minerals and the authigenic dolomite. Microcrystalline and cryptocrystalline 
 quartz corrode all carbonate phases except the calcite that fills fractures. 
 They are thought, therefore, to be the active minerals in the growth of the 
 nodules. 
 
 Fibrous quartz is restricted to void fillings; it occurs only on free 
 surfaces. The youngest mineral is the fracture -filling calcite. The fractures 
 may have formed at any time after the final consolidation of the rocks. Such 
 veins cannot be traced far into the carbonate rock but in the chert they are 
 quite conspicuous. 
 
 FORMATION OF CHERT NODULES 
 
 Pettijohn (1957) recently summarized present theories of the origin 
 of chert. Some workers in the past have favored the hypothesis of syngenetic 
 origin, others have found evidence that the chert bodies were formed by re- 
 placement of the host rock. 
 
10 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 The most commonly accepted criteria supporting the replacement 
 concept are those given by Van Tuyl (1918): 1) the occurrence of chert along 
 fissures in limestone; 2) the very irregular shape of some nodules; 3) the 
 presence of irregular patches of limestone in some cherts; 4) the association 
 of silicified fossils and chert in some limestones; 5) the presence of replaced 
 fossils in some cherts; 6) the failure of some cherts to follow definite zones 
 in limestone formations; 7) the occurrence of silicified oolites formed by the 
 replacement of calcareous ones. 
 
 Additional evidence of replacement is furnished by two points sug- 
 gested by the present study: 1) small quartz bodies in the interstices of the 
 host rock near nodules, and 2) authigenic growth of carbonate minerals of a 
 composition different from that of the host rock associated with the chert. 
 
 Small bodies of quartz in the interstices of the host rock are of ir- 
 regular shape and random disposition about the nodule. They are not always 
 present, but the fact that they are encountered at all is evidence that the 
 associated nodule was never a subspherical mass of silica gel being rolled 
 about on the sea floor. Had this been the case the small bodies surely would 
 have become incorporated in the larger one. Moreover, some of the intersti- 
 tial bodies embay and partially replace fossils, oolites, and other host rock 
 structures. 
 
 The growth of authigenic carbonate minerals associated with chert 
 nodules cannot be explained as a phenomenon of syngenetic chert formation 
 because the authigenic crystals are associated with the lower boundaries of 
 the nodules as well as with their sides and tops. The rhombs concentrated in 
 the host rock near nodules, and distributed through the isolated carbonate 
 masses and the chert proper, have been shown earlier to be authigenic and 
 epigenetic. 
 
 Field Relationships 
 
 In the field, the following evidences of the replacement of chert nodules 
 in carbonate rocks of Illinois are found: 1) masses of host rock are clearly 
 visible in some nodules without the aid of magnification; 2) remnant bedding 
 passes through some nodules; 3) some nodules have the oolitic or coquinoid 
 texture of the rock preserved in silica; 4) euhedral carbonate crystals, some 
 of which are much larger than crystals of the host rock, appear in some 
 nodules; 5) fossils in all stages of replacement are found in many nodules; 
 and 6) zones of silicified carbonate rock appear at the borders of some chert 
 nodules. 
 
 Three negative evidences to support the replacement hypothesis of 
 manner of origin were observed:' 1) no nodules were found with bedding planes 
 bent around them; 2) nodules are not consistently related to any primary 
 structure of the host rock; and 3) dessication cracks, which would be expected 
 in abundance as a result of dehydration of a silica gel, are absent. 
 
 Host-rock Inclusions 
 
 Perhaps the strongest evidence of epigenetic origin is the presence, 
 in all cherts examined for this study, of host-rock material. The occurrence 
 
ILLINOIS NODULAR CHERTS 
 
 11 
 
 of host-rock carbonate has been de- 
 scribed in an earlier section. It varies 
 from large polycrystalline masses down 
 to single crystals. Masses of host rock 
 within a nodule are shown in figure 1, 
 and the texture of one of the masses is 
 shown in plate 1, figure E. 
 
 Remnant Bedding 
 
 Remnant bedding passing through 
 nodules is strong evidence in support 
 of the replacement concept. Syngenetic 
 chert nodules probably would not be 
 bedded at all, and, if they were, it would 
 be difficult to account for their bedding's 
 being continuous with that of the sur- 
 rounding rock. Relict bedding was ob- 
 
 Fig. 2. - Relict bedding in a chert nodule from 
 the Kankankee formation at Savanna, Illinois. 
 Stippled = chert; lined = carbonate 
 
 Fig. 1. - Host-rock masses in chert. 
 Generalized sketch of a nodule from 
 the Galena formation at Menominee 
 Station, Illinois. 
 
 Stippled = chert; lined = carbonate 
 About actual size 
 
 served both on the outcrop and 
 in thin section. A line drawing 
 of relict bedding in a nodule 
 from the Kankakee formation at 
 Savanna, Illinois, is shown in 
 figure 2. 
 
 Preserved Texture 
 
 The preservation of oolit- 
 ic or coquinoid texture of the 
 carbonate rock in the chert is 
 strong evidence of an epigenetic 
 origin for the chert nodules. The 
 texture and fabric of the host 
 rock passes without interruption 
 
 into the chert. This is irreconcilable with the syngenetic hypothesis, which 
 holds that the regions occupied by the nodules had never been filled with the 
 host rock. 
 
 Euhedral Carbonate Crystals 
 
 The presence of euhedral carbonate crystals in chert might be taken 
 as evidence of a syngenetic origin. It might be argued that such crystals 
 grew in the soft silica gel and so were able to complete their euhedral form. 
 This argument would have some validity but for the fact that crystals of the 
 same kind are found in the host rock at nodule boundaries. Close examination 
 reveals that most of the euhedral carbonates are associated with host-rock 
 masses in the chert and many of them actually are contained therein. The 
 relationships of the euhedral carbonates to nodule boundaries and included 
 host-rock masses can best be interpreted as due to epigenetic formation of 
 the chert. 
 
12 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Replaced Fossils 
 
 Many calcareous fossils are found in the chert that have been partially 
 or completely replaced by quartz (plate 1, fig. B). It has been argued that 
 fossils are replaced by being dropped into dehydrating silica gel on the sea 
 floor during sedimentation. The silicified fossils found in this study generally 
 are associated with included host-rock masses that are somewhat replaced by 
 quartz. The fossils, even when separated from recognizable masses of carbon- 
 ate rock, are not found at or near the bottom of nodules, as would be expected 
 of organisms dropped into a gelatinous silica, but are randomly distributed 
 throughout the mass. 
 
 Silicified Carbonate Rock Zones 
 
 Zones of silicified carbonate rock at the edges of chert nodules have 
 been thought to be due to the pressing of carbonate sediments into the still 
 gelatinous silica. This argument fails to account for two conditions. First, 
 the silicified zones are always as thick, and in some instances thicker, 
 around the sides of nodules as at their tops and bottoms. Simple overburden 
 pressure intruding partly consolidated sediments into silica gel would be ex- 
 pected to leave the sides of nodules more or less unaffected. 
 
 Second, a dehydrating silica gel is expected to harden in the peripheral 
 regions first. If impression of carbonate sediments occurred, it would be ex- 
 pected that as deeper, softer zones of the gel mass were reached impression 
 would be easier until finally the carbonate would completely fill the region 
 formerly occupied by the silica gel. The silica would thus be reduced to an 
 interstitial role in a normal carbonate rock. 
 
 Bent Bedding Planes 
 
 Nodules around which bedding planes of carbonate rock are bent are 
 commonly thought to be syngenetic. Actually such a bending of bedding planes 
 around nodules could simply represent differential compaction of the carbon- 
 ate rock and the chert and merely mean that the host formation has undergone 
 some local change in thickness since the chert nodule formed. This phenome- 
 non was not observed in the rocks studied. 
 
 Nodule Distribution 
 
 Syngenetic chert nodules might be expected to be associated with bed- 
 ding planes in the rock. It would be during temporary cessation of carbonate 
 deposition that silica gel would be most likely to form independent nodular 
 masses on the sea floor, and such gel bodies, if covered by later deposits after 
 a reasonable degree of dehydration, might form chert nodules. The nodules 
 found in this investigation are not restricted to such surfaces of nondeposition 
 of carbonate. Rather they are randomly distributed throughout the rocks and 
 are as common in thick beds as in the bedding planes between strata. 
 
ILLINOIS NODULAR CHERTS 13 
 
 Dessication Cracks 
 
 Dessication cracks would be expected if silica gel bodies had hardened 
 into chert nodules. According to Her (1955) silica gels are highly variable in 
 water content, some gels having much more water than silica. The exact na- 
 ture of the silica gels that have been postulated to explain chert nodules has 
 not been stated but it is presumed that a considerable fraction of the volume 
 would be water. Chert is anhydrous. The supposed hardening of a gel body 
 from the outside invites the supposition that the interior portions could harden 
 only as rapidly as water could be lost. This would almost certainly demand 
 that cracks develop in the outer regions. There are no evidences of dessication 
 cracks in the nodules studied. 
 
 Thin-Section Evidence 
 
 In thin-section studies, replacement manner of origin was indicated 
 by 1) the presence of relict masses of host rock; 2) the presence of pseudo- 
 morphs after single crystals or aggregates of crystals; 3) the presence of 
 pseudomorphs after host-rock structures; and 4) the growth of authigenic 
 carbonate minerals of a composition different from those of the host rock in 
 and near nodules. 
 
 Relict Host Rock 
 
 Relict patches of host rock, noted in hand-specimen studies, were also 
 observed in thin section. These patches range in size from fragments of a 
 single crystal to polycrystalline masses 15 centimeters long. In thin section 
 they have not been appreciably changed except by the invasion of quartz around 
 grain boundaries and along cleavage planes. The carbonate crystals at the 
 periphery of the isolated patches are more embayed than those at the center. 
 In many cases, the peripheral grains are highly embayed and partially 
 fringed by isolated fragments of carbonate material in optical continuity with 
 the neighboring crystals of the main mass. 
 
 Relict patches of host rock in various stages of replacement are shown 
 in plate 1, figures E and F, and plate 2, figures A and B. 
 
 The dolomite rhomb at the center of the photograph in plate 1, figure 
 F, is in optical continuity with the dolomite of the surrounding crystal. The 
 dark zone around the rhomb at the center is microcrystalline quartz. The re- 
 placement seems to have taken place along cleavage planes in the original 
 crystal. 
 
 Pseudomorphs After Carbonate Crystals 
 
 In many thin sections, pseudomorphs after carbonate crystals are 
 found in which single crystals of quartz replace several carbonate crystals 
 but preserve the outline of the original carbonate. Plate 1, figure A, shows a 
 single quartz crystal replacing a mosaic of dolomite crystals. The original 
 outlines of the carbonate crystals appear as light lines in the photomicrograph. 
 
14 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Explanation of Plate 1 
 
 A. - Unit metacryst of quartz growing at the expense of dolomite and micro- 
 
 crystalline quartz. Shakopee formation near Utica, Illinois. Crossed 
 nicols, 200X. 
 
 B. - Preservation of a coral upon complete replacement by quartz. Ste. 
 
 Genevieve formation near Anna, Illinois. Plane polarized light, 25X. 
 
 C. - Same as figure D but magnified 57X. 
 
 D. - Calcareous oolite (light) partially replaced by quartz (extinct). Ste. 
 
 Genevieve formation. Crossed nicols, 25X. 
 
 E. - Mass of dolomite isolated within chert. Note the dark ring of iron oxide 
 
 surrounding the dolomite. Galena formation near Menominee Station, 
 Illinois. Plane polarized light, 15X. 
 
 F. - Selective replacement of dolomite along cleavage planes by microcrys- 
 
 talline quartz. The core and rim of the dolomite are optically con- 
 tinuous. The dark rhomb-shaped zone is microcrystalline quartz. 
 Shakopee formation near Utica, Illinois. Crossed nicols, 380X. 
 
Illinois State Geological Survey 
 
 <ik 24. r ., Pi ■ 
 
 Biggs — Petrography and Origin of Nodular Cherts 
 
Illinois State Geological Survey 
 
 ( ib. 245, Plate 2 
 
 Biggs — Petrography and Origin of Nooii \k Cherts 
 
ILLINOIS NODULAR CHERTS 15 
 
 Explanation of Plate 2 
 
 A. - Carbonate crystal (at maximum illumination) between other carbonate 
 
 crystals at extinction displaying a ring of interstitial quartz crystals 
 and a fibrous quartz rosette. Burlington formation near Pearl, 
 Illinois. Crossed nicols, 130X. 
 
 B. - Partially replaced mass of host rock. The quartz in the crinoid stem 
 
 plate is at maximum illumination; the calcite is at extinction. Ste. 
 Genevieve formation near Anna, Illinois. Crossed nicols, 25X. 
 
 C. - Compositionally zoned dolomite crystal in limestone that has replaced 
 
 parts of several calcite crystals. Burlington formation near Pearl, 
 Illinois. Crossed nicols, 130X. 
 
 D. - Chalcedonic quartz showing a dark band at the tips of fibers which may 
 
 be due to concentration of light scattering pores. Burlington formation 
 near Pearl, Illinois. Crossed nicols, 150X. 
 
 E. - Dolomite metacryst probably like that of figure F with the carbonate 
 
 mineral at the center replaced by macrocrystalline quartz. Burlington 
 formation near Florence, Illinois. Crossed nicols, 130X. 
 
 F. - Compositionally zoned carbonate crystal in chert. The core and rim of 
 
 the crystal are ankeritic and the intermediate zone is dolomite. Salem 
 formation, cen. NW 1/4 sec. 18, T. 13 S, R. 1 E. Crossed nicols, 57X. 
 
16 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 The origin of these lines is not understood, but they may be due to slightly 
 different composition of the original material at crystal boundaries. The 
 quartz is a single crystal that extinguishes as a unit. A dolomite crystal par- 
 tially replaced by quartz is shown in the lower central portion of the photo- 
 micrograph. 
 
 Pseudomorphs After Host-rock Structures 
 
 Pseudomorphs in which aggregates of quartz crystals replace carbon- 
 ate rock structures are shown in the completely quartzitized coral in plate 1, 
 figure B, and in the partially replaced oolites in plate 1, figures C and D. Both 
 the coral and the oolites are from the Ste. Genevieve formation near Anna, 
 Illinois. In figure C, the two large oolites have been partially replaced by 
 quartz. The quartz here is at maximum illumination and the calcite is near 
 the extinction position. The white material between oolites is fibrous quartz. 
 In the upper left portion of the figure, other oolites that have been completely 
 replaced are seen. Figure C is the upper large oolite of figure D photographed 
 at greater magnification and rotated so that the quartz is at extinction and the 
 calcite is at maximum illumination. 
 
 It is improbable that the oolites originally formed with this composite 
 arrangement and also unlikely that the oolites were partially replaced in a de- 
 hydrating silica gel. They are part of an uninterrupted oolitic fabric that ex- 
 tends into the host rock. Corals such as that shown in plate 1, figure B, are 
 known to be calcareous forms. This coral has been completely replaced by 
 quartz. It does not lie in the bottom of a nodule, as would be expected had the 
 replacement occurred after it had been covered by a deposit of silica gel. 
 
 Authigenic Carbonates 
 
 Euhedral carbonate crystals are shown in plate 2, figures C, D, and E. 
 The skeletal rhomb in figure C truncates several crystals of the surrounding 
 limestone. This photograph of the limestone was taken about two millimeters 
 from the chert-limestone interface. The number, and degree of completion, 
 of euhedral rhombs increases toward the interface. 
 
 A large euhedral rhomb is seen in plate 2, figure F. It is a zoned 
 ankerite completely surrounded by quartz. Several smaller-rhombs are seen 
 nearby. Dark, vaguely defined masses in the lower part of the photograph are 
 ghosts of completely replaced carbonate crystals that have left small amounts 
 of impurities marking their former position. 
 
 A skeletal dolomite rhomb is shown in plate 2, figure E. It is sur- 
 rounded, and the opening at the center is filled, by microcrystalline quartz. 
 Probably the replacement was controlled by the presence of carbonate of 
 slightly less stable composition at the center of the rhomb. If this was the 
 case, quartz has now completely replaced the less stable phase. 
 
 The relationships of the authigenic carbonates to the boundaries of 
 nodules indicate genetic control by the chert. The rhombs are found in and at 
 the borders of nodules. Those in the central portions of larger nodules seem 
 to have been attacked by the quartz to a greater extent than those at the margins. 
 
ILLINOIS NODULAR CHERTS 17 
 
 Evaluation of Evidence 
 
 There is thus no lack of evidence for the epigenetic origin of cherts 
 studied. Remnant bedding and stringers of carbonate rock in nodules can 
 hardly be explained if it is supposed that the chert originated as gel bodies on 
 the sea floor. 
 
 The preservation of textures and structures implies that the material 
 that is now chert was once homogeneous with the surrounding carbonate rock. 
 It cannot be assumed that oolites and fossils were dropped into a dehydrating 
 gel and there replaced by quartz for this process would have scattered the gel 
 if it were weak enough to permit entry of such small bodies. Moreover, if the 
 gel were very soft and fluid, the likelihood of complete, rather than the common- 
 ly observed partial replacement, probably would be increased. 
 
 Patches of host rock with the same fabric and structure as the sur- 
 rounding carbonate would not be likely to result from crystallization of carbon- 
 ate muds and fossil fragments placed in a silica gel. Some such relict patches 
 of host rock are fifteen to twenty centimeters in the maximum observed di- 
 mension. For a silica gel body on the sea floor to maintain its identity and 
 shape against overburden pressure as it becomes more deeply buried, it must 
 dehydrate and solidify in a comparatively short time. The shrinkage involved 
 in this process would vary with the silica-to-water ratio of the gel but in any 
 case it would not be negligible (Her, 1955). The forces exerted on the included 
 limestone patches by the shrinkage would not be the same as those on the sur- 
 rounding rock of the same composition. The more or less centripetally dis- 
 tributed forces set up by the shrinkage might tend to mold the unconsolidated 
 carbonate material to a more nearly spherical shape and move it toward the 
 nodule's center. Such forces would certainly not promote, and probably would 
 tend to destroy, the very irregular nature of some relict patches of host rock. 
 
 Masses of silica gel might logically be expected to solidify from the 
 outside inward. If this happens it is difficult to explain the silicified limestone 
 around some nodules. If the carbonate material was impressed into the gel 
 while it was soft, a question arises as to what prevented its intruding all the 
 way into the nodule. 
 
 Pseudomorphs after crystals and rock structures cannot occur in syn- 
 geneic chert nodules because presumably no rock structures or crystals of 
 the carbonate host rock were there. 
 
 The association of authigenic dolomite with the chert also would be 
 most improbable if the chert were syngenetic. Syngenetic chert probably would 
 demand syngenetic dolomite, if the relationships that have been observed were 
 found. The dolomite would, of necessity, be deposited at the same time as, 
 and only in association with, the nodules and not between the nodules. Even by 
 this hypothesis it would be difficult to account for the euhedral dolomite crys- 
 tals that are associated with the lower surfaces of the nodules. 
 
 Such evidence supports the belief that chert nodules in Illinois lime- 
 stones and dolomites are epigenetic concretions formed by metasomatic proc- 
 esses. The silica that composes the nodules is considered to have been de- 
 posited synchronously with the carbonate rock as a dispersed phase that ag- 
 gregated into nodules during diagenesis. 
 
18 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Source of Silica 
 
 Chert nodules may be formed from silica introduced into carbonate 
 rocks in several ways. Volcanic springs active on the sea floor may contribute 
 silica directly to the accumulating sediments; hydrothermal solutions may 
 introduce silica into already lithified rocks; groundwater may dissolve silica 
 from siliceous rocks and deposit it in carbonate environments; and silica dis- 
 solved from rocks undergoing subaereal weathering may be transported to the 
 sea and there deposited with the carbonate sediments. 
 
 Volcanic Springs 
 
 Volcanic springs would be expected to leave some evidence of their 
 operations. Silica deposited from them probably would be localized about the 
 vents. Silicified pipes should be found leading downward into older rocks. 
 Moreover, such springs would be localized in one or several portions of the 
 deposition basin, not uniformly distributed over wide areas. Evidence of none 
 of these things was observed in this study. 
 
 Hydrothermal Solutions 
 
 Hydrothermal solutions supplying silica to lithified rocks would be 
 subject to the same restrictions as volcanic springs. Instances where chert 
 is shown to have been deposited from hydrothermal solutions (Fowler et al., 
 1935) are restricted to narrow zones of ore deposition. The lead ores in north- 
 western Illinois and the fluorite ores of southern Illinois are not associated 
 with hydrothermal chert, nor is there any evidence that hydrothermal solutions 
 have produced the chert nodules found elsewhere. 
 
 Groundwater Deposits 
 
 Chert deposited from groundwaters should be restricted to zones of 
 groundwater movement. Thus, chert nodules might be expected to accompany 
 other groundwater deposits. They are not so found. Solution channels are not 
 more common in cherty rocks than elsewhere. Instances in which carbonate 
 rocks have been silicified by groundwaters moving downward through siliceous 
 rocks are known (Rubey, 1952), but the replacement is complete, not nodular. 
 Moreover, the silicified limestone noted by Rubey contains preexisting chert 
 nodules. 
 
 Weathered Silica Deposits 
 
 Silica dissolved in sea water, derived from any source, may be deposit- 
 ed with the sediments. Clarke (1924) estimated that the annual increment of 
 silica contributed to the sea by weathering was 319,000,000 tons. The amount 
 of silicon contained therein would be 150,000,000 tons and is exceeded in 
 Clarke's computations only by calcium (557,000,000 tons) and sodium 
 (258,000,000 tons). Silicon freed by weathering and brought to the sea in 
 streams is thus a more than adequate source for the chert found in carbonate 
 rocks. 
 
ILLINOIS NODULAR CHERTS 19 
 
 Whether the silicon is deposited by organisms or inorganic means is 
 not known in all instances. The fact that silicon is the fourth most abundant 
 cation in limestones (Rankama and Sahama, 1950) is evidence enough that 
 large quantities of it are deposited with the rocks. Pettijohn (1957) cited the 
 presence of interstitial quartz bodies in limestone and they have been observed 
 near chert nodules in this study. 
 
 Evaluation of Sources 
 
 The very widespread occurrence of chert, both areally and stratigraphi- 
 cally, and its random distribution make a volcanic, hydrothermal, or ground- 
 water source of silica most improbable. Evidence for the precipitation of 
 silica from sea water is found in 1) the large amount of silica freed by weather- 
 ing, 2) the large amount of silica carried annually to the seas by rivers, 3) the 
 low concentration of silica in sea water, 4) abundance of silica-secreting 
 organisms and ample opportunity for inorganic precipitation of silica known to 
 exist in the sea, 5) the presence of silica in limestones in a form other than 
 megascopic chert nodules, and 6) the presence of silica in recent carbonate 
 sediments. 
 
 Concentration of Silica to Form Chert Nodules 
 
 Recrystallization tends to occur when rocks are subjected to changes 
 in pressure and temperature. Ramberg (1952), who discussed the relationships 
 of rock components during recrystallization, was concerned chiefly with con- 
 ditions in the field of metamorphism where both pressure and temperature of 
 rock masses vary over wide ranges. 
 
 Diagenesis can be separated from some forms of metamorphism as 
 being different only in the degree of severity of pressure and temperature 
 variations. Correns (1950) defined diagenesis as changes (other than weather- 
 ing) in a sediment between its sedimentation and metamorphism. He found 
 little difficulty in separating changes due to weathering from those of diagenesis 
 but admitted that the boundary between diagenesis and metamorphism is an 
 arbitrary one. 
 
 Perhaps changes in pressure are more important than variations in 
 temperature in causing diagenetic changes. Correns (1950), Pettijohn (1957), 
 and many other workers regard diagenesis as a low-temperature process; 
 the simple overload of superjacent sediments, however, imposes rather large 
 changes in pressure. It may be expected then that it is safe to ignore the 
 effects of temperature in considering the formation of chert nodules. 
 
 Diagenesis of carbonate rocks includes recrystallization of phases 
 formed at the time of deposition. Such recrystallization possibly begins almost 
 immediately after deposition and continues at varying rates for an indefinite 
 period. The process is not simple and so no rate can be assigned to it that 
 would be valid for even identical components in close proximity. 
 
20 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Diagenetic recrystallization may be considered from the standpoint of 
 two relationships stated by Ramberg (1952) as 
 
 
 (1) 
 
 Hx ^ 
 
 where F is the free energy of a phase, P is the pressure on the phase, V is the 
 molal volume of the phase, f c is the force of crystallization, d is the density 
 of the phase, and M is its molecular weight. The subscripts T, X indicate that 
 temperature and composition of the phase are held constant. 
 
 If temperature, T, and pressure, P, in the rock are constant, the con- 
 stituent mineral phases and interstitial fluids are in equilibrium with them- 
 selves and each other; the molal free energy of the crystal, F c , and the corre- 
 sponding components in the surroundings, F , are equal. Because we have 
 made the assumption that T does not vary widely in diagenesis we shall ignore 
 its changes; but if P increases then F must increase, and the phase in question 
 becomes unstable if the pressure is applied to it and only to it. In this case, 
 the crystal should dissolve in whatever phase or phases surround it. 
 
 In the event that F S >F C the crystal may continue to grow even though 
 the pressure on it is greater than that on its surroundings. The force of 
 crystallization was defined by Ramberg (1952) as "the excess pressure which 
 must be applied on a crystal in order that the crystal may be in chemical equi- 
 librium with its surroundings, which are supersaturated to a given degree." 
 
 In a rock containing only a few crystals of a mineral and none of its 
 constituent parts in the pore fluid, the crystals in question should perhaps 
 disappear during recrystallization. If, however, a phase makes up an appreci- 
 able part of the rock, and the pore fluid may be expected to contain some of its 
 constituent ions, the probability rises that any given crystal of the phase may 
 be able to increase in size from dissolved constituents. If some crystals by 
 reason of a favorable position continue to grow, the removal of constituent 
 ions from the pore fluid permits further decomposition of nearby crystals 
 that are unstable. Thus a mechanism whereby larger crystals grow at the ex- 
 pense of the smaller is established. 
 
 Recrystallization of limestones after deposition leads to the growth and 
 purification of crystals. Any silica occluded in the carbonate minerals or 
 crystallized in the rock is affected by the process just as the carbonate miner- 
 als are. Some quartz crystals whose free energy is lower than that of SiO£ 
 in the surroundings will remain stable during recrystallization and grow at 
 the expense of other quartz. In such a densely packed medium the space for 
 growth afforded to the quartz is slight indeed. A growing crystal can replace 
 other crystals provided it has a higher force of crystallization and a supply of 
 constituent ions. The force of crystallization of quartz, by equation 2 above, 
 is greater than that of calcite or dolomite. Therefore, we should expect to 
 find that replacement of carbonate by quartz is common, but that replacement 
 of quartz by carbonate is not so frequently obvious. Carbonate crystals must 
 
ILLINOIS NODULAR CHERTS 21 
 
 replace quartz crystals, however, where ever the phases carbonate and quartz 
 are in contact and the surroundings are supersaturated with carbonate con- 
 stituents but deficient in silicon ions. 
 
 Perhaps not all quartz found in the rock formed around a nucleus of 
 quartz that was stable from the beginning of diagenesis. Activated particles, 
 Si and 0"~ions, may nucleate quartz crystals on mineral interfaces when, 
 
 by reason of locally lower pressure or other anomaly, crystals may form at 
 weak supersaturation. Once formed, these newly nucleated crystals can grow 
 at the expense of surrounding crystals. 
 
 Favorable sites for such nucleation are probably found in 1) open voids 
 formed by the shells of organisms; 2) small fractures opened in the rock; and 
 3) pressure shadows developed around coherent bodies in the rock. These, or 
 similar sites, provide low-pressure areas where crystal nuclei may form from 
 relatively dilute pore fluids. Once nucleated, quartz crystals continue to grow 
 if a supply of constituent ions is available or if the crystal is stressed beyond 
 its equilibrium value they will resorb. 
 
 Theoretically, quartz growth should fill open spaces before new growth 
 begins replacing other crystals. The actual growth of quartz bodies in carbon- 
 ate rocks proceeds in this fashion, as is evidenced by the incomplete replace- 
 ment of carbonate minerals at the nodule boundary and by the occurrence of 
 small quartz bodies in the interstices of the limestone outside the nodule. The 
 apparent method of growth is complex, involving the formation of a small 
 quartz core surrounded by a diffuse halo of partially replaced host rock. The 
 diffuse area continues to grow outward into the limestone accompanied by 
 growth of the more or less carbonate-free core of firm chert. 
 
 The excellent preservation of structures and textures and the lack of 
 any evidence for displacement of the structures suggest that the replacement 
 is isovolumetric. Barth (1948) supposed that such replacement occurred with- 
 out movement of the oxygen ions. Concerning the role of oxygen in replace- 
 ment he says : 
 
 "In view of what has been said in the preceding paper about the role of 
 the oxygen ion in rocks and in mineral lattices, it is reasonable to suppose that 
 the mechanism of such isovolumetric alterations is that of a migration and ex- 
 change of cations in a medium composed of relatively stationary oxygen ions. 
 Only in this way can one explain the preservation of the delicate structural 
 features; for removal of the large oxygen ions would break up the minerals 
 and destroy the fragile and fine structure patterns. In harmony with this idea 
 is, e.g., the mechanism of the weathering of biotite (bleaching, baueritization), 
 which is effected by selective removal of the metal ions while oxygen and 
 silicon remain in the residual lattice." 
 
 The shape of chert nodules is dictated by the ease of replacement of 
 the host rock. Because the host rock is essentially isotropic in this respect, 
 the nodules often approach sphericity. Because they are somewhat flattened 
 parallel to the bedding of the host rock, the nodules commonly have the form 
 of oblate spheroids. This flattening is due to the greater ease of replacing 
 the host rock in the horizontal plane. Replacement in the vertical plane must 
 take place against overburden pressure. Pressure on the upper and lower 
 surfaces of the nodule would be expected to be greater than that on the sides, 
 and would thus lower the growth rate of the quartz. 
 
22 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 Zones in the host rock that are, for any reason, more resistant to re- 
 placement than others, complicate the shape of the nodules. A stylolite or shale 
 zone in the limestone commonly results in a flat side on an otherwise rounded 
 nodule. Smaller inhomogeneities in the limestone cause indentations in the 
 surface of the nodule. 
 
 The chert-limestone contact generally is irregular as seen in thin section. 
 Stringers of quartz invade the interstices between calcite crystals and partially 
 replace them. Individual crystals of carbonate minerals and islands of host 
 rock are more abundant near the contact than deeper within the nodule. The 
 central portions of large nodules generally are composed of quartz with little 
 or no carbonate present. 
 
 The contact area is in many instances marked by large, concentrically 
 zoned carbonate rhombs. The rhombs are most common on the host-rock side 
 of the interface. Their composition varies from dolomite to ankerite. The 
 position of the zoned rhombs, crowded at the chert-limestone interface, 
 suggests that they are products of the interaction of the quartz and the carbon- 
 ate of the host rock. This suggestion is strengthened by the fact that the zoned 
 carbonates are more common in impure limestone than in other rocks. 
 
 If calcite crystals containing small amounts of magnesium and iron 
 were replaced by quartz, it is probable that the two impurity elements would 
 find more stable positions by concentrating at the replacement front. At the 
 contact of the limestone and quartz, crystal structures are already weakened. 
 The magnesium and iron would find entry and be able to form mixed crystals 
 with the calcium already present. Such crystals would be more stable with 
 respect to the quartz than clacite with slight impurities because enough mag- 
 nesium and iron would be added to complete the structure. The mixed crystals 
 formed would have a lower free energy and better ordering, and so be more 
 stable than the solid solution of the original calcite. 
 
 The increased stability of the dolomite rhombs is shown by the fact 
 that they are less corroded in the chert than are similar fragments of lime- 
 stone. 
 
 Special Characteristics of Chert in Dolomite 
 
 Chert nodules formed in dolomite contain fewer fossils than do those 
 found in limestone. This is possibly due to the destruction of fossils during 
 the dolomitization. If the paucity of fossils is due to such destruction, the 
 chert nodules must have been formed at or later than the time of dolomitization. 
 Generalizations can not be made about the time of dolomitization of limestones 
 as each dolomitized formation is an individual problem. Careful study of the 
 relations of the chert nodules to the host rock might help to solve the time -of - 
 dolomitization problem. 
 
 Nodules from dolomites contain more carbonates than do those from 
 limestones, and the chert fills interstices to a greater extent. This may be 
 due to the aggregation of chert after the limestone has been replaced by dolo- 
 mite. Perhaps the dolomite was more stable with respect to quartz than cal- 
 cite, and the silica was forced to fill interstices to a much greater extent. 
 
ILLINOIS NODULAR CHERTS 23 
 
 AGE OF CHERT NODULES STUDIED 
 
 The problem of assigning an age for the chert nodules has not been 
 solved. Early workers held that chert was formed only at the weathering 
 interface. This idea became untenable, however, as well records showing the 
 presence of chert far from the outcrop became common. 
 
 Other ideas of a late genesis have not been so easily disproved. The 
 general lack of association of chert nodules with ore deposits, groundwater 
 channelways, or other secondary features of the rocks weighs against any 
 hypothesis claiming the chert to be much younger than the enclosing formation. 
 
 The presence of residual chert conglomerates in Illinois was noted by 
 Poor (1925). He found that the detrital chert in the basal conglomerate of the 
 Pottsville formation in southern Illinois contained fossils of Chester age (late 
 Mississippian). Chert pebbles bearing Chester age fossils could not occur in 
 the Pottsville formation if the genesis of the chert was much later than the de- 
 position of the Chester rocks. The same relationship of Mississippian age 
 chert pebbles in the basal conglomerate of the Pottsville formation was ob- 
 served by Rubey (1952) in the Hardin and Brussels quadrangles. 
 
 Delicate fossils commonly are found in the chert whereas their counter- 
 parts in the limestone are shattered. Bryozoa found in the chert of both the 
 St. Louis and Ste. Genevieve formations are better preserved than those in the 
 surrounding limestone. The most probable reason for better preservation is 
 that the fossils were incorporated in chert early in the history of the deposit 
 before overload crushed them. The chert would resist crushing much better 
 than would the relatively incompetent limestone. Some crushed fossils have 
 been found in the cherts but they are thought to have been broken before re- 
 placement. If the better fossil preservation is due to protection by a more 
 rigid matrix, chertification must have preceded or at least accompanied the 
 compaction and lithifi cation of the rock. 
 
 In thin section the same replacement phenomena are seen. Delicate 
 macrofossils are better preserved in the chert than in the limestone. Included 
 host-rock patches, however, have the same texture as the surrounding rock, 
 so the nodules probably are diagenetic in age rather than syngenetic. That 
 host-rock patches in a rigid chert nodule would undergo recrystallization re- 
 sulting in the same texture as that of the host rock outside the nodule is un- 
 likely because the patches would not have had the same thermal and pressure 
 history as the carbonate minerals outside the nodules. 
 
 The high porosity and permeability of poorly consolidated sediments 
 (Pettijohn, 1957) and the plentiful supply of chemically active aqueous solutions 
 would favor the aggregation of chert during diagenesis. Better preservation 
 of delicate fossils in the cherts and the presence of residual cherts of an age 
 but little younger than the parent formation are evidences favoring an early 
 time of origin for chert. The similar texture of host rock outside the nodules 
 and included host-rock patches is evidence that the chert was aggregated no 
 earlier than the recrystallization of the host rock. 
 
 It seems that many, if not most, chert nodules in the rocks studied, 
 originated during the recrystallization of the host rocks. The time that the 
 nodules ceased to grow is harder to state. Probably they increase in size 
 
24 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 until the chemical and physical factors controlling the process cease to oper- 
 ate because of interference by outside factors. The rate of growth probably 
 has varied from one nodule to another, and probably has not been uniform with- 
 in the same nodule. No evidence of recent growth of nodules was found. The 
 growth probably ceases altogether when rocks come into the zone of weathering. 
 
 SUMMARY AND CONCLUSIONS 
 
 The silica mineral present in the nodular cherts of the carbonate rocks 
 of Illinois is quartz. This determination, based on study of material in thin 
 section, is supported both by infrared absorption and x-ray diffraction studies. 
 All cherts examined contain some carbonate minerals. Some of the carbonate 
 materials are fragments of host rock or individual crystals having the dis- 
 tinctive markings of the crystals in the host rock. Others are authigenic dolo- 
 mite crystals which generally differ in composition from the carbonates of 
 the formation. Quartz and the carbonates, calcite and dolomite, make up the 
 bulk of the chert. Fluorite and iron oxide are present in minor portions in 
 some chert. 
 
 The only evidence that might favor a syngenetic origin of the nodules 
 is the presence of better preserved fossils in the chert than in the carbonate 
 rock. As has been shown, this is really a criterion of age, not manner of for- 
 mation. Other evidence of syngenetic origin is lacking. Remnant bedding, 
 textural preservation, patches of host rock, authigenic dolomite crystals, 
 partially-to-completely replaced fossils, rim zones of silicified limestone, 
 pseudomorphs of crystals or aggregates of crystals, and pseudomorphs of 
 rock structures in the nodules are all considered evidence that the nodules 
 originated by replacement of the pre-existing host rock. 
 
 The chert nodules and the rocks in which they occur offer no evidence 
 favorable to the hypothesis that the silica was introduced after the consolidation 
 of the original rock. It is certain that siliceous organisms, which are rare in 
 Illinois rocks, cannot be considered a source of silica for chert formation. 
 
 The most probable source of the large quantities of silica found in 
 cherts is the weathering of land masses. Large quantities of dissolved silicon 
 are brought to the sea each year. Moreover, it is known that Si is not 
 
 concentrated in the sea but must be deposited almost as fast as it is brought 
 into the sea. Silica is thought to be deposited along with other sediments be- 
 cause they commonly show siliceous cementation, and because Si is the 
 fourth most abundant cation in limestones. 
 
 Silica may be deposited with the carbonate rocks by organic or inorganic 
 processes and probably precipitation actually occurs due to both processes. 
 Seemingly, the inorganic mechanism would be more nearly ubiquitous than or- 
 ganic precipitation, but organisms may be locally important. The presence of 
 silica in the limestones is a matter of record, though further studies should be 
 made to show quantitatively how much quartz a given limestone holds. 
 
 The preservation of fossils and rock textures in chert, seems to indi- 
 cate that the replacement occurred between the beginning of diagenesis and 
 uplift. The replacement of the limestone was not complete. Fragments of 
 structures and textures of the host rock present in the chert refute the syn- 
 genetic hypothesis and make it possible to understand the origin of these cherts. 
 
ILLINOIS NODULAR CHERTS 25 
 
 REFERENCES 
 
 Barth, T. F. W., 1948, Oxygen in rocks: A basis for petrographic calcula- 
 tions: Jour. Geology, v. 56, p. 50. 
 
 Clarke, F. W., 1924, The data of geochemistry: U. S. Geol. Survey Bull. 770. 
 
 Correns, C. W., 1950, The geochemistry of diagenesis: Geochim. et Cosmo- 
 chim. Acta, v. 1, p. 49-54. 
 
 Emmons, R. C, 1943, The Universal Stage: Geol. Soc. America Memoir 8. 
 
 Folk, R. L., and Weaver, C. E., 1952, A study of the texture of composition 
 of chert: Am. Jour. Sci., v. 250, p. 498-510. 
 
 Fowler, G. M., Lyden, J. P., Gregory, F. E., and Agar, W.M., 1935, Chert- 
 ification in the Tri-State mining district: Am. Inst. Mm. Met. Eng. 
 Trans., v. 115, p. 106-163. 
 
 Her, Ralph K., 1955, The colloid chemistry of silica and silicates: Cornell 
 University Press, Ithaca, New York. 
 
 Keller, W. D., 1941, Petrography and origin of the Rex chert: Geol. Soc. 
 America Bull., v. 52, p. 1279-1298. 
 
 Pelto, C. R., 1956, Chalcedony: Am. Jour. Sci. v. 254, p. 32-50. 
 
 Pettijohn, F. J., 1957, Sedimentary rocks: Harper and Brothers, New York. 
 
 Poor, R. S., 1925, The character and significance of the basal conglomerate 
 of the Pennsylvanian syskra in Southern Illinois; Illinois Acad. Sci. 
 Trans., v. 18, p. 371-374. 
 
 Ramberg, Hans, 1952, The origin of metamorphic and metasomatic rocks: 
 Univ. Chicago Press, Chicago. 
 
 Rankama, Kalervo, and Sahama, Th. G., 1950, Geochemistry: Univ. Chicago 
 Press, Chicago. 
 
 Rubey, W. W., 1952, Geology and mineral resources of the Hardin and Brussels 
 quadrangles (in Illinois): U. S. Geol. Survey Prof. Paper 218. 
 
 Van Tuyl, F. M., 1918, The origin of chert: Am. Jour. Sci., ser. 4, v. 45, 
 p. 449-456. 
 
Illinois State Geological Survey Circular 245 
 25 p. , 2 figs. , 2 pis. , 2 tables, 1957 
 

 CIRCULAR 245 
 
 ILLINOIS STATE GEOLOGICAL SURVEY 
 
 URBANA