DOCSLIB.ORG

Stratigraphy and Structure Castleton Area Vermont

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

STRATIGRAPHY AND STRUCTURE OF THE CASTLETON AREA VERMONT I By PHILLIP FOWLER VERMONT GEOLOGICAL SURVEY CHARLES G. DOLL, State Geologist - Published by VERMONT DEVELOPMENT COMMISSION MONTPELIER, VERMONT BULLETIN NO. 2 1950 SECOND PRINTING 1958 CONTENTS PAGE Abstract 5 Introduction 6 General ......................... 6 Acknowledgments . . . . . . . . . . . . . . . . . . . 8 Previous work ...................... 9 Regional physiography .................. 10 Drainage ........................ 11 Valley sequence . . . . . . . . . . . . . . . . . . . . . 13 General ......................... 13 Mendon series ...................... 14 Lower Cambrian series .................. 17 Cheshire quartzite ................... 17 Dunham dolomite . . . . . . . . . . . . . . . . . . 18 Monkton quartzite ................... 20 Winooski dolomite ................... 20 Lpper Cambrian series .................. 21 Danby formation .................... 22 Clarendon Springs dolomite ............... 23 Lower Ordovician series .................. 24 Boardman formation .................. 24 Bascom formation ................... 27 Ordovician—Chazy group ................. 28 Burchards limestone . . . . . . . . . . . . . . . . . 28 Beldens formation ................... 29 Middlebury limestone .................. 30 Ordovician—Trenton group ................ 31 Orwell limestone .................... 31 Whipple marble .................... 32 Hortonville slate .................... 34 Taconic sequence ...................... 37 General ......................... 37 Lower Cambrian series .................. 38 Nassau formation ................... 38 Bomoseen grit ..................... 46 Mettawee slate .................... 47 Eddy Hill grit ..................... 49 PAGE Schodack formation .................. 50 Zion Hill quartzite ................... 53 Ordovician system .................... 55 Normanskill formation ................. 55 Pre-Ordovician unconformity . . . . . . . . . . . . . 57 Dikes ........................... 58 Structural geology ..................... 59 Major features ...................... 59 General setting .................... 59 Folds ......................... 61 Faults ..........................2 Taconic overthrust ................... Minor features ...................... Cleavage . . . . . . . . . . . . . . . . . . . . . . 69 Joints ......................... 71 Drag folds and flowage folds ............... 71 Time of deformation ................... 71 Metamorphism ....................... 72 Historical geology . . . . . . . . . . . . . . . . . . . . 74 Economic geology . . . . . . . . . . . . . . . . . . . . 78 References cited ...................... 80 Illustrations FIGURE 1. Geographic location of Castleton area . 7 2. Columnar sections of strata ................12 3. Major structural features of Castleton quadrangle and vicinity .................60 PLATE I. Correlation of Castleton area with ad- joining regions . Following page 57 II. Geological map of Castleton quadrangle .......In pocket III. Structure sections A-A' and B-B' ..........In pocket IV. Structure sections C-C' and D-D'..........In pocket STRATIGRAPHY AND STRUCTURE OF THE CASTLETON AREA, VERMONT PHILLIP FOWLER ABSTRACT During this investigation approximately two-thirds of the Castleton quadrangle was mapped geologically. The sedimentary rocks of the Castleton area belong to two stratigraphic sequences, contrasting in lithology and more or less parallel in time. The 10,000-foot Champlain Valley (Autochthonous, Valley) sequence includes Lower Cambrian or Pre-Cambrian clastics, Lower and Upper Cambrian dolomites and quartzites, Lower Ordovician and Chazyan marbles and dolomites, and Trenton marble, dolomite, and black slate. Although the widespread lithologic discordance between the Lower Cambrian Cheshire quartzite and the underlying Mendon series has been interpreted by some as an angular unconformity, it is here in- terpreted as due to facies changes within the Mendon series. Middle Cambrian is missing probably because of non-deposition. Erosional disconformities probably intervene between the Lower Ordovician and the Chazy and between the Chazy and the Black River-Trenton. Slight warping and subaerial erosion in middle Trenton time produced a significant unconformity. The 30004000-foot Taconic sequence crops out in the Taconic Range and the slate belt. The thick phyllite, quartzite, and grit that underlies the Taconic Range was formerly considered to be Upper Ordovician and was called the Berkshire schist. Because of its relations to the Cambrian slates of the slate belt and its similarity to the Nassau formation of New York it is here mapped as the Nassau formation. Above the probably late Pre-Cambrian Nassau formation lie Lower Cambrian slate, lime- stone, quartzite and grit separated by an erosional disconformity from Lower(?) and Middle Ordovician slate, grit, chert, and quartzite. The rocks of the Valley sequence exhibit broad, deep folds and one small break thmst. The Taconie sequence is a comparatively thin sheet super- ficially crumpled into isoclinal folds. The chief problem in this area is to account for the anomalous juxtaposition of the Cambro-Ordovician argillaceous Taconic sequence and the Cambro-Ordovician carbonate Valley sequence. The principal objective of this investigation was to ascertain the validity of Keith's concept of the Taconic overthrust, which is assumed to be a huge strip thrust that carried the Taconic sequence from the east westward to overlie the Valley sequence. Evidence for the fault in this area consists of lithologic discordance above and below the fault trace, large-scale structural discordance between the two sequences, the contrast between contemporaneous sequences of two dissimilar facies, the presence of klippen and fensters, and the exist- ence of the late Pre-Cambrian Nassau formation lying above Ordovician rocks of the Valley sequence. The Taconic overthrust is believed to be proved. The rocks of the Taconic sequence may have been laid down in the vicinity of the modem Connecticut Valley, and if so the minimun net slip on the Taconic overthrust must be about 50 miles. The folding, faulting, jointing, cleavage, and metamorphism of the rocks of both sequences took place probably near the close of the Ordo- vician period. The earlier stages of the Taconic orogeny produced a flow cleavage oriented parallel to the axial planes of the folds. During the later stages of the orogenv the first cleavage was folded by forces applied in a direction slightly different from those that produced the first cleavage. These later forces developed an axial plane shear cleavage. The northwestern third of the Castleton quadrangle was not investi- gated in detail, and data on that part of the quadrangle were obtained for the geological map from previous publications. INTRODUCTION General The Castleton area (Fig. 1) covers about 130 square miles in west- central Vermont and eastern New York. During this investigation all the rocks of the Castleton quadrangle that lie south of the Castleton River were mapped. In the northern part of the quadrangle only the rocks lying east of the Taconic Range were mapped. The remainder of the Castleton quadrangle has been mapped geologically in recent years by Kaiser (1945) and Cady (1945) . * *Referenc are given at end of the paper. 6 74 73 ° 72° 45° ---- ---.- .45° I I4 •St.Albans •1 (_I I - xz-I_-I L () -J Monkti • c: 44 0 Q) ( Mddlbury 440 ? V I Brendon N.H. .j.Rutland e ) Qj Bald'ICo ________2 l L 43 I N.Y. Bennington N.H. _lAlbany Becreft Mtn. c_Il ç lMass. 42° (fJ. 42° 73° 72° N.Y ______________ 0 10 20 30 40 __ Poughkeeosie MILES ' I i. Castleton Quadrangle 2. Saratoga District 3. Capital District 4. Taconic Quadrangle 740 FIGURE 1. GEOGRAPHIC LOCATION OF CASTLETON AREA AND OTHER PLACES MENTIONED IN THE TEXT. 7 Much of the Castleton area is occupied by a small part of the Tacoruc Range, which lies in east-central New York and adjacent parts of Vermont and Massachusetts. Nearly forty years ago Arthur Keith concluded that the Cambro-Ordovician rocks of the Taconic Range in Vermont are a klippe or thrust outlier composed of an argillaceous facies that had been thrust westward over a carbonate facies of similar age. Although this concept has found general acceptance among geologists working in the area, the roots of the overthrust have not been found. Moreover, modern detailed stratigraphic and structural studies have not been made in much of the Taconic region. The Castleton area was chosen in order to ascertain the validity of the concept of a large Taconic overthrust. Originally this study was confined to the rocks of the Taconic sequence, but it became evident that a clear picture of the relation between the Taconic sequence and the rocks of the marble belt bordering the Taconic Range on the east required remapping of the part of the marble belt that lies in the Castleton quadrangle. This investigation, therefore, has carried the mapping of the Champlain and Vermont Valleys (Cady, 1945) to the southern border of the Castleton quadrangle. Folding, faulting, and metamorphism of the rocks have made accurate strati- graphic work difficult. Identifiable fossils are rare, and the thickness of several formations is obscure. The area was mapped by the pace-and-compass method aided by Paulin altimeter and aerial photographs. Data were plotted on photo- static copies
Recommended publications
  • State Ge?Logical Survey

    State Ge?Logical Survey

    ILLINOIS State Ge?logical Survey BULLETIN NO. 1. THE GEOLOGICAL MAP OF ILLINOIS BY STUART WELLER. URBANA: UNIVERSITY OF ILLINOIS. 1906. SPRINGFIELD: lLLI:\'OIS STATE JOURNAL Co., STATE PRINTBRs· 1 9 0 6 ., STATE GEOLOGICAL COMMISSION GOVERNOR C. S. DENEEN, Chairman, PROFESSOR T. C. CHAMBERLIN, V·ice-Oha·irman. PRESIDENT EDMUND J. JAMES Secretary. H. FOSTER BAIN, Director. ·1 CONTENTS. PAGE. Letter of transmittal.... .. .. .. ..... ..... ...... .. ... ......... .. .. .... Introduction .................................................................... ..... 8 Purpose of a geological map.............................. ............................... 8 Sources of material . .. .. .. .. .. .. .. .. .. .. ........ .... 8 Lines of deformation .............................. ........................ 11 Geological formations represented ................................ rn Cambrian........................ ........ ..... .. 13 Potsdam sandstone .. ...... ...................... 1:J Ordovician ............................................... ........................... ...... 14 Lower Magnesian limestone.......................... ... ........ 14 St. Peters sandstone . ... .... .... .. .. ..... ..... ...... .. ... ... H Trenton-Galena formation ............................................ ............... 1r:i Cincinnatian formation.... .. ...... .. .. .. .. ...... .. .... 16 Silurian ......... ...... .... .. .... ....... .... ............ ........ .... .. ...... .... .. .... ...... 17 N iag-aran limestone.... .. .. .. .. .. ... ........ ... 17 Devonian..............................
  • An Analysis of Multiple Trackways of Protichnites Owen, 1852, from the Potsdam Sandstone (Late Cambrian), St

    An Analysis of Multiple Trackways of Protichnites Owen, 1852, from the Potsdam Sandstone (Late Cambrian), St

    AN ANALYSIS OF MULTIPLE TRACKWAYS OF PROTICHNITES OWEN, 1852, FROM THE POTSDAM SANDSTONE (LATE CAMBRIAN), ST. LAWRENCE VALLEY, NY by Matthew E. Burton-Kelly A Bachelors Thesis Submitted to the Faculty of the Department of Geology of St. Lawrence University in partial fulfillment of the requirements for the degree of Bachelor of Science with Honors in Geology Canton, New York 2005 1 2 3 This thesis submitted by in partial fulfillment of the requirements for the degree of Bachelor of Science with Honors in Geology from St. Lawrence University is hereby approved by the Faculty Advisor under whom the work was done. Faculty Advisor Date Department Chairman Date ii 4 ACKNOWLEDGMENTS The author would like to thank Dr. J. Mark Erickson for his assistance and guidance throughout the course of this project, as well as the St. Lawrence University Geology Department, which provided research materials and covered transportation costs. Attendance at the annual meeting of the Northeastern Section of the Geological Society of America to present preliminary results was funded by the Jim Street Fund, St. Lawrence University Geology. Jim Dawson provided vital insight into the nature of these trackways. Any number of additional people provided support for the author, most notably Camille Partin, Trisha Smrecak, and Joanne Cavallerano, but thanks go out to all the members of the St. Lawrence University Geology Department and the St. Lawrence University Track and Field teams. iii 5 TABLE OF CONTENTS THESIS APPROVAL..........................................................................................................ii
  • Mechanical Properties of St. Peter Sandstone a Comparison of Field and Laboratory Results a Thesis Submitted to the Faculty of T

    Mechanical Properties of St. Peter Sandstone a Comparison of Field and Laboratory Results a Thesis Submitted to the Faculty of T

    MECHANICAL PROPERTIES OF ST. PETER SANDSTONE A COMPARISON OF FIELD AND LABORATORY RESULTS A THESIS SUBMITTED TO THE FACULTY OF THE GRADUATE SCHOOL OF THE UNIVERSITY OF MINNESOTA BY MICHAEL EUGENE DITTES IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE DECEMBER, 2015 This thesis contains previously published material (Appendix E) in the “Journal of Geotechnical and Geoenvironmental Engineering” © 2002 ASCE. All other material © 2015 Michael E. Dittes All Rights Reserved. ACKNOWLEDGMENTS I would like to extend my thanks to those, who without their help I would not have been able to bring this project to completion. First and foremost, I thank Professor Joseph Labuz who took a chance on me, by offering me a TA-ship. Through my time in school, Joe helped me stay focused when I started to move off on tangents, offered timely advice, and over the years has become much more than my advisor. I am proud to think of him as a friend. Professors Andrew Drescher and Peter Huddleston also deserve special thanks for providing critical review of my work, and agreeing to sit on my thesis committee. To Ms. Tiffany Ralston who had an uncanny way of knowing what I needed to do, and how, before I knew myself. To Charles Nelson who helped me streamline my thesis project and helped me gain access to the Minnesota Library Archives construction site. To my fellow graduate students with whom I debated, joked and laughed, you helped me see things that I was missing. Your input was invaluable and you have my deep appreciation.
  • Fossils from the Lower Cambrian of Bornholm

    Fossils from the Lower Cambrian of Bornholm

    CHR. POULSEN FOSSILS FROM THE LOWER CAMBRIAN OF BORNHOLM Det Kongelige Danske Videnskabernes Selskab Matematisk-fysiske Meddelelser 36, 2 Kommissionær: Munksgaard København 1967 Synopsis A Lower Cambrian fauna from Bornholm consisting of 34 species is described. The ol- dest of the Lower Cambrian rocks, the Balka quartzite, contains trace fossils referable to Diplocraterion, Tigillites, and Skolithos, and in addition to these some worm remains com- parable to Byronia MATTHEW. After a hiatus follows siltstone („Green shales” of several au- thors) and Bispebjerg sandstone which represent one single cycle of sedimentation. The silt- stone contains a rich fauna which is essentially endemic. Two new genera and seventeen new species are established. The Lower Cambrian age of the siltstone appears clearly from the occurrence of Fordilla troyensis WALCOTT and Hyolilhellus micans BILLINGS. The Bispebjerg sandstone has only yielded a fragment of Hyolithellus micans and a single specimen of the trace fossil Cruziana dispar LINNARSSON. The conditions of sedimentation and the stratigra- phical position of the Bornholm Lower Cambrian are disscussed. PRINTED IN DENMARK BIANCO LUNOS BOGTRYKKERI A-S CONTENTS Page Preface 5 Introduction 6 The sediments 7 Fossils from the Balka quartzite 13 Annelida 13 Genus et sp. ind. (cf. Byronia MATTHEW) 13 Trace fossils 13 Fossils from the siltstone ("Green shales") 14 Porifera 14 Genus et sp. ind. I (cf. Pyrifonema MCov) 14 — — — — II 15 III 15 Pelecypoda 15 Fordilla Iroyensis WALCOTT 15 Genus et sp. ind. 16 Monoplacophora 17 Proplina? prfsca n. sp. 17 Pollicino? cambrica (MOBERG) 18 Gastropoda 19 Prosinuites bornholmensis n. g. et n. sp. 19 Calyptoptomatida 20 Circotheca sp.
  • The Spence Shale Lagerstätte: an Important Window Into Cambrian Biodiversity

    The Spence Shale Lagerstätte: an Important Window Into Cambrian Biodiversity

    Downloaded from http://jgs.lyellcollection.org/ by guest on September 24, 2021 Accepted Manuscript Journal of the Geological Society The Spence Shale Lagerstätte: an Important Window into Cambrian Biodiversity Julien Kimmig, Luke C. Strotz, Sara R. Kimmig, Sven O. Egenhoff & Bruce S. Lieberman DOI: https://doi.org/10.1144/jgs2018-195 Received 31 October 2018 Revised 21 February 2019 Accepted 28 February 2019 © 2019 The Author(s). This is an Open Access article distributed under the terms of the Creative Commons Attribution 4.0 License (http://creativecommons.org/licenses/by/4.0/). Published by The Geological Society of London. Publishing disclaimer: www.geolsoc.org.uk/pub_ethics Supplementary material at https://doi.org/10.6084/m9.figshare.c.4423145 To cite this article, please follow the guidance at http://www.geolsoc.org.uk/onlinefirst#cit_journal Downloaded from http://jgs.lyellcollection.org/ by guest on September 24, 2021 The Spence Shale Lagerstätte: an Important Window into Cambrian Biodiversity 1* 1,2 1,3 4 1,2 Julien Kimmig , Luke C. Strotz , Sara R. Kimmig , Sven O. Egenhoff & Bruce S. Lieberman 1Biodiversity Institute, University of Kansas, Lawrence, KS 66045, USA 2 Department of Ecology & Evolutionary Biology, University of Kansas, Lawrence, KS, USA 3Pacific Northwest National Laboratory, Richland, WA 99354, USA 4Department of Geosciences, Colorado State University, Fort Collins, CO 80523, USA *Correspondence: [email protected] Abstract: The Spence Shale Member of the Langston Formation is a Cambrian (Miaolingian: Wuliuan) Lagerstätte in northeastern Utah and southeastern Idaho. It is older than the more well- known Wheeler and Marjum Lagerstätten from western Utah, and the Burgess Shale from Canada.
  • The Origin of Tetraradial Symmetry in Cnidarians

    The Origin of Tetraradial Symmetry in Cnidarians

    The origin of tetraradial symmetry in cnidarians JERZY DZIK, ANDRZEJ BALINSKI AND YUANLIN SUN Dzik, J., Balinski, A. & Sun, Y. 2017: The origin of tetraradial symmetry in cnidarians. Lethaia, DOI: 10.1111/let.12199. Serially arranged sets of eight septa-like structures occur in the basal part of phosphatic tubes of Sphenothallus from the early Ordovician (early Floian) Fenxi- ang Formation in Hubei Province of China. They are similar in shape, location and number, to cusps in chitinous tubes of extant coronate scyphozoan polyps, which supports the widely accepted cnidarian affinity of this problematic fossil. However, unlike the recent Medusozoa, the tubes of Sphenothallus are flattened at later stages of development, showing biradial symmetry. Moreover, the septa (cusps) in Sphenothallus are obliquely arranged, which introduces a bilateral component to the tube symmetry. This makes Sphenothallus similar to the Early Cambrian Paiutitubulites, having similar septa but with even more apparent bilat- eral disposition. Biradial symmetry also characterizes the Early Cambrian tubular fossil Hexaconularia, showing a similarity to the conulariids. However, instead of being strictly tetraradial like conulariids, Hexaconularia shows hexaradial symme- try superimposed on the biradial one. A conulariid with a smooth test showing signs of the ‘origami’ plicated closure of the aperture found in the Fenxiang For- mation supports the idea that tetraradial symmetry of conulariids resulted from geometrical constrains connected with this kind of closure. Its minute basal attachment surface makes it likely that the holdfasts characterizing Sphenothallus and advanced conulariids are secondary features. This concurs with the lack of any such holdfast in the earliest Cambrian Torellella, as well as in the possibly related Olivooides and Quadrapyrgites.
  • Proquest Dissertations

    Proquest Dissertations

    STRATIGRAPHIC AND STRUCTURAL FRAMEWORK OF THE POTSDAM GROUP IN EASTERN ONTARIO, WESTERN QUEBEC AND NORTHERN NEW YORK STATE by B.V. Sanford CANADA'S PARLIAMENT BUILDINGS CONSTRUCTED FROM SANDSTONE OF THE NEPEAN FORMATION A thesis submitted to the School Of Graduate Studies in partial fulfillment of the requirements of the degree of Ph.D. in Earth Sciences OTTAWA- CARLETON GEOSCIENCE CENTRE UNIVERSITY OF OTTAWA OTTAWA, ONTARIO CANADA © BV Sanford, 2007 Library and Bibliotheque et 1*1 Archives Canada Archives Canada Published Heritage Direction du Branch Patrimoine de I'edition 395 Wellington Street 395, rue Wellington Ottawa ON K1A0N4 Ottawa ON K1A0N4 Canada Canada Your file Votre reference ISBN: 978-0-494-49395-3 Our file Notre reference ISBN: 978-0-494-49395-3 NOTICE: AVIS: The author has granted a non­ L'auteur a accorde une licence non exclusive exclusive license allowing Library permettant a la Bibliotheque et Archives and Archives Canada to reproduce, Canada de reproduire, publier, archiver, publish, archive, preserve, conserve, sauvegarder, conserver, transmettre au public communicate to the public by par telecommunication ou par Plntemet, prefer, telecommunication or on the Internet, distribuer et vendre des theses partout dans loan, distribute and sell theses le monde, a des fins commerciales ou autres, worldwide, for commercial or non­ sur support microforme, papier, electronique commercial purposes, in microform, et/ou autres formats. paper, electronic and/or any other formats. The author retains copyright L'auteur conserve la propriete du droit d'auteur ownership and moral rights in et des droits moraux qui protege cette these. this thesis. Neither the thesis Ni la these ni des extraits substantiels de nor substantial extracts from it celle-ci ne doivent etre imprimes ou autrement may be printed or otherwise reproduits sans son autorisation.
  • An Inventory of Trilobites from National Park Service Areas

    An Inventory of Trilobites from National Park Service Areas

    Sullivan, R.M. and Lucas, S.G., eds., 2016, Fossil Record 5. New Mexico Museum of Natural History and Science Bulletin 74. 179 AN INVENTORY OF TRILOBITES FROM NATIONAL PARK SERVICE AREAS MEGAN R. NORR¹, VINCENT L. SANTUCCI1 and JUSTIN S. TWEET2 1National Park Service. 1201 Eye Street NW, Washington, D.C. 20005; -email: [email protected]; 2Tweet Paleo-Consulting. 9149 79th St. S. Cottage Grove. MN 55016; Abstract—Trilobites represent an extinct group of Paleozoic marine invertebrate fossils that have great scientific interest and public appeal. Trilobites exhibit wide taxonomic diversity and are contained within nine orders of the Class Trilobita. A wealth of scientific literature exists regarding trilobites, their morphology, biostratigraphy, indicators of paleoenvironments, behavior, and other research themes. An inventory of National Park Service areas reveals that fossilized remains of trilobites are documented from within at least 33 NPS units, including Death Valley National Park, Grand Canyon National Park, Yellowstone National Park, and Yukon-Charley Rivers National Preserve. More than 120 trilobite hototype specimens are known from National Park Service areas. INTRODUCTION Of the 262 National Park Service areas identified with paleontological resources, 33 of those units have documented trilobite fossils (Fig. 1). More than 120 holotype specimens of trilobites have been found within National Park Service (NPS) units. Once thriving during the Paleozoic Era (between ~520 and 250 million years ago) and becoming extinct at the end of the Permian Period, trilobites were prone to fossilization due to their hard exoskeletons and the sedimentary marine environments they inhabited. While parks such as Death Valley National Park and Yukon-Charley Rivers National Preserve have reported a great abundance of fossilized trilobites, many other national parks also contain a diverse trilobite fauna.
  • New Finds of Skeletal Fossils in the Terminal Neoproterozoic of the Siberian Platform and Spain

    New Finds of Skeletal Fossils in the Terminal Neoproterozoic of the Siberian Platform and Spain

    New finds of skeletal fossils in the terminal Neoproterozoic of the Siberian Platform and Spain ANDREY YU. ZHURAVLEV, ELADIO LIÑÁN, JOSÉ ANTONIO GÁMEZ VINTANED, FRANÇOISE DEBRENNE, and ALEKSANDR B. FEDOROV Zhuravlev, A.Yu., Liñán, E., Gámez Vintaned, J.A., Debrenne, F., and Fedorov, A.B. 2012. New finds of skeletal fossils in the terminal Neoproterozoic of the Siberian Platform and Spain. Acta Palaeontologica Polonica 57 (1): 205–224. A current paradigm accepts the presence of weakly biomineralized animals only, barely above a low metazoan grade of or− ganization in the terminal Neoproterozoic (Ediacaran), and a later, early Cambrian burst of well skeletonized animals. Here we report new assemblages of primarily calcareous shelly fossils from upper Ediacaran (553–542 Ma) carbonates of Spain and Russia (Siberian Platform). The problematic organism Cloudina is found in the Yudoma Group of the southeastern Si− berian Platform and different skeletal taxa have been discovered in the terminal Neoproterozoic of several provinces of Spain. New data on the morphology and microstructure of Ediacaran skeletal fossils Cloudina and Namacalathus indicate that the Neoproterozoic skeletal organisms were already reasonably advanced. In total, at least 15 skeletal metazoan genera are recorded worldwide within this interval. This number is comparable with that known for the basal early Cambrian. These data reveal that the terminal Neoproterozoic skeletal bloom was a real precursor of the Cambrian radiation. Cloudina,the oldest animal with a mineralised skeleton on the Siberian Platform, characterises the uppermost Ediacaran strata of the Ust’−Yudoma Formation. While in Siberia Cloudina co−occurs with small skeletal fossils of Cambrian aspect, in Spain Cloudina−bearing carbonates and other Ediacaran skeletal fossils alternate with strata containing rich terminal Neoprotero− zoic trace fossil assemblages.
  • Microbiofacies Analysis of Cambrian Offshore Carbonates from Sardinia (Italy): Environment Reconstruction and Development of a Drowning Carbonate Platform

    Microbiofacies Analysis of Cambrian Offshore Carbonates from Sardinia (Italy): Environment Reconstruction and Development of a Drowning Carbonate Platform

    Carnets de Géologie / Notebooks on Geology - Article 2006/01 (CG2006_A01) Microbiofacies analysis of Cambrian offshore carbonates from Sardinia (Italy): environment reconstruction and development of a drowning carbonate platform Olaf ELICKI1 Abstract: The Campo Pisano Formation of southwestern Sardinia is represented by an offshore carbonate succession spanning the latest Early to late Middle Cambrian. Paleogeographically, the fauna is characteristic of western Perigondwana, and indicates faunal relations to France, Spain, and Turkey. Microfaunal paleoecology reflects drowning of an isolated carbonate platform at tropical latitudes. Sessile epibenthic filter feeders dominate at the base, succeeded upward by sessile, epibenthic, suspension feeders. Upsection, a shift in the ratio of faunal groups indicates increasing replacement by mobile epibenthos. Autochthonous faunal elements decline near the top where allochthonous taxa become important. In the basal portion of the formation the faunal succession indicates relatively shallow neritic habitats with a moderate influx of suspended sediment, followed by a period of slightly deeper neritic conditions. Probably a shallow bathyal environment was established at the transition to the overlying siliciclastic Cabitza Formation. The bathymetric and ecofacies changes in the Campo Pisano Formation are interpreted as having been caused by a discontinuous rise in eustatic sea-level, probably accompanied by subsidence due to tensional tectonics. The depositional environment was that of a distal open-marine shelf or ramp without strong relief. This interpretation is supported by the lack of significant lateral changes in the fossil assemblages, and an upward deepening of facies. The applied micropaleoecological approach is proven a powerful tool in regional stratigraphy and in the reconstruction of sedimentary realms in the Mediterranean Cambrian, particularly when high-resolution biostratigraphic data and diagnostic sedimentary characteristics are sparse.
  • The Wisconsin Sandstones

    The Wisconsin Sandstones

    The Wisconsin Sandstones The Manufacturer and Builder, Vol. 17, Issue 12 December 1885, pg. 274 This article, which begins on the next page, is presented on the Stone Quarries and Beyond web site. http://quarriesandbeyond.org/ Peggy B. Perazzo Email: [email protected] September 2013 The Wisconsin Sandstones The Manufacturer and Builder, Vol. 17, Issue 12, December 1885, pg. 274 “We present herewith a summary of the report of Prof. Allan D. Conover, special agent of the United States census, on the sandstones of Wisconsin, as published in the volume of building stones lately issued from the Census Office. “The great bed of Silurian rocks which almost complete encircles the Archæan area of northern central Wisconsin, had, previous to the last census year, furnished practically all of the building stone quarried within the State. Every one of the grand divisions of the belt furnishes in one or more localities material fit for ordinary building purposes, though stone suitable for the finer class of work is as yet quarried at but few places. Within the Silurian area, to which the more thickly settled portions of the State pretty closely correspond, except where a very deep covering of glacial drift exists, there are but few regions where rock fit for the most ordinary building purposes cannot be obtained everywhere within a few miles, and almost every large town or city has within its limits, or near by, quarries of sufficient capacity to supply its own most pressing needs for that sort of building material. But there were, previous to 1880, no localities (except at Bass Island in the Lake Superior region) where building stone had been quarried in any quantity for export beyond the State, and but a few where it had been quarried for other than a local market.
  • Smithsonian Miscellaneous Collections

    Smithsonian Miscellaneous Collections

    SMITHSONIAN MISCELLANEOUS COLLECTIONS VOLUME 116, NUMBER 5 Cfjarle* £. anb Jfflarp "^Xaux flKHalcott 3Resiearcf) Jf tmb MIDDLE CAMBRIAN STRATIGRAPHY AND FAUNAS OF THE CANADIAN ROCKY MOUNTAINS (With 34 Plates) BY FRANCO RASETTI The Johns Hopkins University Baltimore, Maryland SEP Iff 1951 (Publication 4046) CITY OF WASHINGTON PUBLISHED BY THE SMITHSONIAN INSTITUTION SEPTEMBER 18, 1951 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOLUME 116, NUMBER 5 Cfjarie* B. anb Jfflarp "^Taux OTalcott &egearcf) Jf unb MIDDLE CAMBRIAN STRATIGRAPHY AND FAUNAS OF THE CANADIAN ROCKY MOUNTAINS (With 34 Plates) BY FRANCO RASETTI The Johns Hopkins University Baltimore, Maryland (Publication 4046) CITY OF WASHINGTON PUBLISHED BY THE SMITHSONIAN INSTITUTION SEPTEMBER 18, 1951 BALTIMORE, MD., U. 8. A. CONTENTS PART I. STRATIGRAPHY Page Introduction i The problem I Acknowledgments 2 Summary of previous work 3 Method of work 7 Description of localities and sections 9 Terminology 9 Bow Lake 11 Hector Creek 13 Slate Mountains 14 Mount Niblock 15 Mount Whyte—Plain of Six Glaciers 17 Ross Lake 20 Mount Bosworth 21 Mount Victoria 22 Cathedral Mountain 23 Popes Peak 24 Eiffel Peak 25 Mount Temple 26 Pinnacle Mountain 28 Mount Schaffer 29 Mount Odaray 31 Park Mountain 33 Mount Field : Kicking Horse Aline 35 Mount Field : Burgess Quarry 37 Mount Stephen 39 General description 39 Monarch Creek IS Monarch Mine 46 North Gully and Fossil Gully 47 Cambrian formations : Lower Cambrian S3 St. Piran sandstone 53 Copper boundary of formation ?3 Peyto limestone member 55 Cambrian formations : Middle Cambrian 56 Mount Whyte formation 56 Type section 56 Lithology and thickness 5& Mount Whyte-Cathedral contact 62 Lake Agnes shale lentil 62 Yoho shale lentil "3 iii iv SMITHSONIAN MISCELLANEOUS COLLECTIONS VOL.