1 0 0 w Amber, Resinite, and Fossil Resins 7.f 1 6 0 5- 9 9 1 k- b 1/ 2 0 1 0. 1 oi: org 6 | d cs.99 a1 bs.5, 12 | http://pun Date: May 0o 6, 2cati uly 1Publi J In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. 1 0 0 w 7.f 1 6 0 5- 9 9 1 k- b 1/ 2 0 1 0. 1 oi: org 6 | d cs.99 a1 bs.5, 12 | http://pun Date: May 0o 6, 2cati uly 1Publi J In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. ACS SYMPOSIUM SERIES 617 Amber, Resinite, and Fossil Resins 1 Ken B. Anderson, EDITOR 0 0 w Argone National Laboratory 7.f 1 6 0 5- 99 John C. Crelling, EDITOR 1 k- 1/b Southern Illinois University—Carbondale 2 0 1 0. 1 oi: org 6 | d cs.99 a1 12 | http://pubs.n Date: May 5, Dbeyv ethlaoetp teDhdeiv f2ris0oi8omtnh ao Nfs yaGmteioponocahsileu mMmies tserptyion,n gIs nocr.e, d 0o of the American Chemical Society, uly 16, 2Publicati AWugausshti n2g1t-o2n5,, D C19,9 4 J American Chemical Society, Washington, DC 1995 In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. Library of Congress Cataloging-in-Publication Data Amber, resinite, and fossil resins / Ken B. Anderson, editor, John C. Crelling, editor. p. cm.—(ACS symposium series, ISSN 0097-6156; 617) "Developed from a symposium sponsored by the Division of Geo chemistry, Inc., at the 208th National Meeting of the American Chemical Society, Washington, D.C., August 21-25, 1994." Includes bibliographical references and indexes. 1 0 0 w ISBN 0-8412-3336-5 7.f 61 1. Resins, Fossil—Congresses. 2. Amber—Congresses. 5-0 3. Resinite—Congresses. 4. Organic geochemistry—Congresses. 9 9 1 I. Anderson, Ken B., 1962- . II. Crelling, John C. III. American bk- Chemical Society. Division of Geochemistry, Inc. IV. American 1/ Chemical Society. Meeting (208th: 1994: Washington, D.C.) 2 0 V. Series. 1 0. oi: 1 5Q5E39.27'95—.A6d3c 20 1995 95-44645 org 6 | d CIP cs.99 a1 bs.5, 12 | http://pun Date: May TChoipsy briogohkt ©is p1r9i9n5t ed on acid-free, recycled paper. 0o 6, 2cati American Chemical Society July 1 Publi Achlla pRteigr hitns tRhiess evrovleudm. e Tinhdei caaptepse atrhaen cceo poyfr igthhet ocwodneer 'ast ctohnes ebnott tthomat roefp rthoeg rfaiprshti cp caogpei eosf oef atchhe chapter may be made for personal or internal use or for the personal or internal use of specific clients. 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The citation of trade names and/or names of manufacturers in this publication is not to be construed as an endorsement or as approval by ACS of the commercial products or services referenced herein; nor should the mere reference herein to any drawing, specification, chemical process, or other data be regarded as a license or as a conveyance of any right or permission to the holder, reader, or any other person or corporation, to manufacture, reproduce, use, or sell any patented invention or copyrighted work that may in any way be related thereto. Registered names, trademarks, etc., used in this publication, even without specific indication thereof, are not to be considered unprotected by law. PRINTED IN THE UNITED STATES OF AMERICA In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. 1995 Advisory Board ACS Symposium Series Robert J. Alaimo Cynthia A. Maryanoff Procter & Gamble Pharmaceuticals R. W. Johnson Pharmaceutical Research Institute Mark Arnold University of Iowa Roger A. Minear University of Illinois 1 00 David Baker at Urbana-Champaign w 17.f University of Tennessee Omkaram Nalamasu 6 5-0 Arindam Bose AT&T Bell Laboratories 9 9 Pfizer Central Research 1 k- Vincent Pecoraro b 1/ Robert F. Brady, Jr. University of Michigan 2 10 Naval Research Laboratory 0. George W. Roberts 1 oi: Mary E. Castellion North Carolina State University org 6 | d ChemEdit Company cs.99 John R. Shapley bs.a5, 1 Margaret A. Cavanaugh University of Illinois 12 | http://pun Date: May ANUnartitvihoenursaril t yBS c.o ifeE nWlcleiiss cF oonusnind aatti oMn adison DCoonautc ugUrlrrabesna tnA aT.- eCSchhmnaiomtlhopg aiiegsn C orporation 0o 6, 2cati Gunda I. Georg L. Somasundaram uly 1Publi University of Kansas DuPont J Madeleine M. Joullie Michael D. Taylor University of Pennsylvania Parke-Davis Pharmaceutical Research Lawrence P. Klemann William C. Walker Nabisco Foods Group DuPont Douglas R. Lloyd Peter Willett The University of Texas at Austin University of Sheffield (England) In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. Foreword 1HE ACS SYMPOSIUM SERIES was first published in 1974 to provide a mechanism for publishing symposia quickly in book form. The purpose of this series is to publish comprehensive books developed from symposia, which are usually "snapshots in time" of the current research being done on a topic, plus 1 0 0 some review material on the topic. For this reason, it is neces w 7.f sary that the papers be published as quickly as possible. 1 06 Before a symposium-based book is put under contract, the 5- 9 proposed table of contents is reviewed for appropriateness to 9 1 k- the topic and for comprehensiveness of the collection. Some b 1/ papers are excluded at this point, and others are added to 2 10 round out the scope of the volume. In addition, a draft of each 0. 1 paper is peer-reviewed prior to final acceptance or rejection. org 6 | doi: Terhsi)s oanf othney msyoumsp orseivuimew, wphrooc besesc oims es uthpee rveidsietod r(bsy) othf et hoer gbaonoikz. cs.99 a1 The authors then revise their papers according to the recom bs.5, 12 | http://pun Date: May wmcahemon edcrAaahts-ie roceanka s dr tyuh olaefct, o abpoloyln t,nl hyea cnoetdhrs isegsa iurnybrae mlvr eiirteve wistsheeieaors rnc fshi anh naapldv a eppt ahebpreese e rnesa d nmtidot oa dortsher,ie. g ipenrdaelip toarrerse , 0o 6, 2cati view papers are included in the volumes. Verbatim reproduc uly 1Publi tions of previously published papers are not accepted. J In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. Preface AMBER IS AN EXTRAORDINARY MATERIAL. Among sedimentary organic products, it is unique for its exceptional preservation (and the exceptional preservation of materials included within it); for its value as an "organic gemstone"; and for the extraordinary role it has played in human history, especially European history. Until the 18th century, when fossil fuels became important in sustaining the industrial revolution, amber was the single most important organic product from the geosphere. 1 Whether one is discussing Roman invasions, the excesses of the Teutonic 0 0 pr Knights, or the secretive and powerful amber guilds, throughout (and 7. 1 undoubtedly before) recorded history, war and intrigue have always sur 6 0 5- rounded control of the production and distribution of amber. Indeed, at 9 19 one time gallows stood on the shores of the Baltic, and any unfortunate bk- sole caught collecting amber without proper authority was summarily put 1/ 2 to the gibbet! 0 1 0. However, it is not our purpose to describe the remarkably colorful 1 oi: and often bloody history of the amber trade. Rather, this book has been org 6 | d assembled to report, as far as is possible in a rapidly developing field, the acs.199 current state of the art in scientific (especially chemical) studies of amber. ubs.y 5, The unique properties of fossil resins make them exceptional candidates 12 | http://pn Date: Ma gapsere ospceohretvemen itacinaaldl mppraroortkceeecsrtss emso.af t eprAaiallelssoo ,ee nnvtchiareso endum nwepinatthrsai,n ll setehldeeidmm eahnbatisal irtoyyp econofen dda iumtipob neosrps, p aontrod 0o tunities in molecular paleontology that could not previously be addressed, uly 16, 2Publicati imnicllluiodnin yge athrse orledc. overy of fragmentary DNA from insects more than 100 J Because of its extraordinary properties, amber is of interest to scien tists in a wide range of disciplines. The symposium upon which this book is based was organized to provide a forum for a diverse exchange of infor mation and to present an opportunity for investigators to become familiar with the challenges facing scientists working with amber in a range of dis ciplines. Likewise, this book was prepared to present a diverse summary of our current knowledge of the nature and properties of fossil resins. Ambers are derived from biological materials (resins) that have been incorporated into sediments. Their chemical properties are a conse quence of both their biological origins and the geological environment into which they were deposited and in which they have subsequently matured. Hence, it is important, when assessing the properties and ix In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. characteristics of these materials, to take these factors into account. For this reason, in addition to reporting chemical studies of ambers, including structural characterization, isotopic composition, maturation studies, resinite-derived oils, and amino acid distributions, the reports in this book also discuss aspects of the biology, geology, petrology, and technology of fossil resins. Acknowledgments This book and the symposium from which it developed are a result of the efforts and support of a large number of individuals and organizations. Hence, we express our gratitude to the ACS Division of Geochemistry, Inc., that sponsored the symposium, to the speakers and authors whose work is reported in this volume, and to those individuals who generously 1 donated their time to review the papers. The Petroleum Research Fund 0 0 pr is also acknowledged for their support by allowing several speakers from 7. 1 outside North America to attend and participate in the symposium 6 0 5- (ACS-PRF 29052-SE). The support of the U.S. Department of Energy 9 9 for Κ. B. Anderson, under Contract No. W-31-109-ENG-38, is also 1 bk- gratefully acknowledged. 1/ 2 0 0.1 KEN B. ANDERSON 1 oi: Chemistry Division org 6 | d Argonne National Laboratory acs.199 9700 South Cass Avenue ubs.y 5, Argonne, IL 60439 pa 12 | http://n Date: M JDOeHpaNrt mC.e nCtR EofL GLIeNoGlo gy 0o Southern Illinois University 6, 2cati Carbondale, IL 62901 uly 1Publi J September 5, 1995 x In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. Introduction Ken B. Anderson and John C. Crelling Scientific analysis of fossil resins is not new. In fact, the term electron is derived from the Greek word for amber, "Electra". In recent years however, scientific analysis of these materials has undergone a renaissance and the pace of new discoveries concerning these materials has quickened considerably. The principle reason for this is 1 0 0 the advent and application of modern analytical techniques, which have allowed pr 7. researchers to address questions which could not be addressed previously. The scope 1 06 of these discoveries has been exceptionally broad, and significant advances have been 95- achieved in a number of disciplines based on the results of studies of ambers or 9 k-1 materials included within it. b 1/ This brief introduction has been prepared to assist the reader by defining important 2 0 terms, discussing some of the broad issues which are presently being discussed among 1 10. scientists working with fossil resins, and to briefly mention some aspects of work oi: related to ambers which are not covered in the papers in the body of this volume. org 6 | d acs.199 Definitions and Nomenclature: ubs.y 5, The title of this book, and the symposium from which it has been developed, "Amber, 12 | http://pn Date: Ma Rnsyoenmsoinenniytceml aaotnuudrse Fa onofsd st hmile aRsyee sbmiena sut"es,re rideafl silne. cteTtrsoc f hrmaonamgne ytha bwel yoor.uk tOesertsth, etthhrsee shdeoif wfteiecruvmletsry, ahwraeivt lhea rtihgneesl iyst ed that 0o these terms are not synonymous and that each should be used only in specific 6, 2cati circumstances. For example, some authors have insisted that the term "amber" should uly 1Publi only be used to describe Baltic Amber. Other authors contend that the term "resinite", J which is primarily a coal maceral term and hence is defined by ICCP (7) and ASTM (2) convention, should only be used to describe material which has been petrographically identified (by optical microscopy). It has also been suggested that the terms "amber" and "resinite", differ only in that "resinite" refers to microscopic materials and "amber" refers to macroscopic materials. In the opinion of the present authors, while for some purposes it may be convenient to precisely define these terms, in reality their use is so widespread and so varied that it is futile to attempt to narrowly define their meanings. Therefore, for practical purposes they should be regarded as synonymous. Where a specific or more precise meaning is intended, the writer or speaker should explicitly indicate this. For the purposes of this Introduction, these terms will be treated as synonyms. The term "resin" (used alone) should be used only for modern samples. 0097-6156/95/0617-OOxi$12.00/0 © 1995 American Chemical Society In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996. It is also important at the outset to discuss the scope of the terms "Amber", "Resinite" and "Fossil Resins". For the purpose of this discussion, these materials are defined as: "solid, discrete organic materials found in coals and other sediments as macroscopic or microscopic particles, which are derived from the resins of higher plants" This definition is based on the definition given in an earlier report by one of the authors (3). It is not comprehensive, nor do all of the contributors to this volume necessarily adopt this definition in their own reports. It does however, serve as a general working definition and as a basis for further discussion. The two principle aspects of this definition are (i) fossil resins must be solid, discrete bodies, and (ii) that they must be derived fromt he resins of higher plants. The first of these two components serves to exclude resin(ite) derived products and material which has become dispersed at a molecular level, such as woody fossils from which resin derived materials can be extracted, and resinite derived oils. This is not to suggest that these materials are not important or worthy of investigation, but, simply that they should not be referred to using the same terms used for discrete macroscopic 1 00 and microscopic fossil resins. pr 7. The second component of this definition, which serves to exclude montan waxes 1 6 and similar materials, which are sometimes (rather perversely) referred to "wax 0 95- resinite" (4) and which are clearly not related in either biochemical origin, botanical 9 k-1 function, or composition to other forms of fossil resin, is more problematic. The 1/b difficulty here centers around the question of what constitutes a resin. Terpenoid 2 0 resinites, especially polyterpenoid resinites undoubtedly constitute the vast majority of 1 0. currently known resinites. However, it is entirely possible that some plants may now, 1 oi: or may in the past, have produced non-terpenoid exudates to fulfill the biological and org 6 | d ecological functions now filled in most plants by terpenoid resins, and this definition is acs.199 certainly not intended to exclude non-terpenoid forms of resinite. Very little is known ubs.y 5, concerning the evolution of terpenoid resins. It is not even clear when terpenoid resins pa first appear in the fossil record. The oldest definitively terpenoid resin characterized 012 | http://on Date: M biinny fP othramlee aoatzuioothnico frsrseo dimsim rreeepnsoitnsrt,iet eedss p tooelc dbieaelr l Tythr ciaaonsa sCliscr,,e b(taAuctne lodituetrlsse oi msn r,o aUlreenc.up luRabrel sicsihnhaietrdeas cr teaesrrueizl taostf)ito,e nbn u ortef pthoertseed 6, 2cati materials has been done. uly 1Publi Further complicating the nomenclature of fossil resins is the plethora of geological J names given to various samples. Names for ambers based on locality, discoverer etc, abound in the literature, (eg; Glessite, Rumanite, Chemawinite, Burmite, Simetite, Bitterfelderite, Settlingite, Walchowite, Schraufite, Schilerseeite, Simetite, Stantienite, etc ). However, as virtually none of these names is based on any knowledge of the composition of the amber, they are of little or no scientific value in comparing samples. Many of these names are so heavily entrenched in popular usage and in the scientific literature that it is not possible to restrict their usage. Classification of Ambers: As an attempt to rationalize the nomenclature of these materials and to provide a logical basis for comparison of ambers for the purposes of scientific discussion, a classification system, based on the structural characteristics of the amber itself has been proposed (3,5,6),. This classification system has not yet been universally xii In Amber, Resinite, and Fossil Resins; Anderson, K., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1996.