SEDIMENT PROVENANCE INFLUENCES ON COMPOSITIONAL CHANGE FROM SOURCE TO SINK Edited by R M AJAT AZUMDER Department ofApplied Geology,FacultyofEngineeringandScience,CurtinUniversity, Sarawak,Malaysia AMSTERDAM(cid:129)BOSTON(cid:129)HEIDELBERG(cid:129)LONDON(cid:129)NEWYORK(cid:129)OXFORD PARIS(cid:129)SANDIEGO(cid:129)SANFRANCISCO(cid:129)SINGAPORE(cid:129)SYDNEY(cid:129)TOKYO Elsevier Radarweg29,POBox211,1000AEAmsterdam,Netherlands TheBoulevard,LangfordLane,Kidlington,OxfordOX51GB,UnitedKingdom 50HampshireStreet,5thFloor,Cambridge,MA02139,UnitedStates Copyright©2017ElsevierInc.Allrightsreserved. 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LibraryofCongressCataloging-in-PublicationData AcatalogrecordforthisbookisavailablefromtheLibraryofCongress BritishLibraryCataloguing-in-PublicationData AcataloguerecordforthisbookisavailablefromtheBritishLibrary ISBN:978-0-12-803386-9 ForinformationonallElsevierpublications visitourwebsiteathttps://www.elsevier.com/ Coarsetoverycoarse-grainedscoriaceoussandstone(darkcolored)interbandedwithfinesandstone/siltstone (lightcolored)andmudstone(brownish),Mio-PlioceneMisakiFormation,MiuraPeninsula,Japan.Thecoarse sandstonesarenormallygraded(turbidites)andwerederivedfromvolcanoes.Thefinerclasticsareindigenous backgroundsedimentsformedinadeepmarinesedimentarybasin(2000e3000mdeep)inanarc-arccollision zoneandthushavedifferentsedimentprovenancefromthecoarserclastics.Mostofthesoftsediment deformationstructurespreservedwithinlaterallycontinuousandselectivestratigraphichorizonshavebeen interpretedasseismite. Publisher:CandiceJanco AcquisitionEditor:AmyShapiro EditorialProjectManager:TashaFrank ProductionProjectManager:PaulPrasadChandramohan Designer:MathewLimbert TypesetbyTNQBooksandJournals Dedicated to my wife, Sumana Mazumder, for her support and positivity. Contributors D. Abbott City College of New York, New P. Dasgupta Durgapur Government College, York, NY, United States; Lamont-Doherty Durgapur,India Earth Observatory of Columbia University, S.De Presidency University,Kolkata,India Palisades,NY,UnitedStates W. deLorraine St. Lawrence Zinc Company, P.Acquafredda UniversitàdegliStudidiBari, Gouverneur, NY,UnitedStates Bari,Italy A.Dey Jadavpur University,Kolkata,India A. Agangi Curtin University, Bentley, WA, P.G. Eriksson University of Pretoria, Pretoria, Australia SouthAfrica J.S. Armstrong-Altrin Universidad Nacional C.L. Fergusson University of Wollongong, AutónomadeMéxico,México D.F.,México Wollongong,NSW,Australia S. Balakrishnan Pondicherry University, V. Festa Università degli Studi di Bari, Bari, Pondicherry, India Italy R.Baldacconi Freelancer,Taranto, Italy C.R.L.Friend Glendale,Oxon,UnitedKingdom A. Basu Indiana University, Bloomington, IN, K. Galinskaya Brooklyn College, New York, UnitedStates NY,UnitedStates V.C. Bennett The Australian National S. Ghosh Presidency University, Kolkata, University,Canberra,ACT,Australia India P.K.Bose JadavpurUniversity, Kolkata,India V.Gusiakov TsunamiLaboratory,ICMMGSD D. Breger Lamont-Doherty Earth Observatory RAS,Novosibirsk,Russia ofColumbia University,Palisades,NY,United Y. Han China University of Geosciences, States; Micrographic Arts, Saratoga Springs, Beijing,China NY,UnitedStates Z. Han Shandong University of Science and N.Chakraborty JadavpurUniversity,Kolkata, Technology,Qingdao,China India R.A. Henderson James Cook University, P.P. Chakraborty University of Delhi, New Townsville,QLD,Australia Delhi,India A. Hofmann University of Johannesburg, M.A.Chan UniversityofUtah,SaltLakeCity, AucklandPark,SouthAfrica UT,UnitedStates K.Horie NationalInstituteforPolarResearch, J. Chiarenzelli St. Lawrence University, Tokyo,Japan Canton,NY, UnitedStates M. Ibanez-Mejia Massachusetts Institute of A.R. Chivas University of Wollongong, Technology, Cambridge, MA, United States; Wollongong,NSW, Australia UniversityofRochester,Rochester,NY,United G. da Costa University of Johannesburg, States AucklandPark,SouthAfrica J. Jong JX Nippon Oil and Gas Exploration K. Das Hiroshima University, Higashi- (Deepwater Sabah) Limited, Kuala Lumpur, Hiroshima,Japan Malaysia xi xii CONTRIBUTORS F.L. Kessler Goldbach Geoconsultants O & G, R. Offler University of Newcastle, Callaghan, Glattbach,Aschaffenburg, Germany NSW, Australia D. Kratzmann Santa Rosa Junior College, M. Pisarska-Jamroz_y Geological Institute, Petaluma,CA,UnitedStates Adam MickiewiczUniversity,Poznan(cid:2),Poland S.Lisco UniversitàdegliStudidiBari,Bari,Italy G.Rambolamanana UniversityofAntananarivo, D.G.F. Long Laurentian University, Sudbury, Antananarivo,Madagascar ON,Canada C.A. Rosiere Federal University of Minas M. Lupulescu New York State Museum, Gerais, BeloHorizonte,Brazil Albany,NY,UnitedStates S.Saha University ofDelhi,NewDelhi, India A.Mandal JadavpurUniversity,Kolkata,India S.Sanyal JadavpurUniversity, Kolkata,India G.Mastronuzzi UniversitàdegliStudidiBari, S.Sarkar Jadavpur University,Kolkata,India Bari,Italy T.Sato INPEXCorporation,Tokyo, Japan R. Mazumder Curtin University, Sarawak, R.Scotti Freelancer, Taranto, Italy Malaysia B. Selleck Colgate University, Hamilton, NY, W. Mejiama Osaka City University, Osaka, UnitedStates Japan P. Sengupta Jadavpur University, Kolkata, M.Moretti UniversitàdegliStudidiBari,Bari, India Italy G. Shanmugam The University of Texas at V.Moretti RegionePugliaeServizioEcologiae Arlington, Arlington, TX,UnitedStates Ufficio Programmazione, Politiche Energetiche, H.A.Tawfik TantaUniversity, Tanta,Egypt Bari, Italy M. Tropeano Università degli Studi di Bari, S. Mukherjee Jadavpur University, Kolkata, Bari,Italy India Y. Tsutsumi National Science Museum, J. Mukhopadhyay Presidency University, Tsukuba,Japan Kolkata, India; University of Johannesburg, AucklandPark,SouthAfrica A.J. (Tom) Van Loon Geocom Consultants, Benitachell, Spain R. Nagarajan Curtin University, Miri, Sarawak,Malaysia G.M. Young University of Western Ontario, London, ON,Canada R.Nagendra AnnaUniversity, Chennai,India A.P. Nutman University of Wollongong, Wol- longong,NSW,Australia;ChineseAcademyof GeologicalSciences, Beijing,China C H A P T E R 1 fl Sediment Provenance: In uence on Compositional Change From Source to Sink R. Mazumder Curtin University, Sarawak, Malaysia O U T L I N E Acknowledgment 4 References 4 Theterm“provenance”originatesfromtheLatinword“provenire,”meaningtooriginate. Although commonly used to indicate source or parent rock from which sediments were generated, the term “provenance” actually encompasses all factors related to sediment production, with “specific reference to the composition of the parent rocks as well as the physiography and climate of the source area” (Weltje and Eynatten, 2004). Sedimentary provenance data play a critical role in assessing palaeogeographic reconstructions, in constraining lateral displacements in orogens, in characterizing crust that is no longer exposed, in mapping depositional systems, in subsurface correlation, and in predicting reservoir quality (Haughton et al., 1991; Weltje and Eynatten, 2004; Garzanti et al., 2014; Bhattacharya et al., 2016). The source to sink (S2S) is an approach that connects areas of sediment production with sites of transfer and locations of storage through the quantification of earth processes in a budgetary manner (Walsh et al., 2016; Bhattacharya et al., 2016). Understandably, sediment transport, climate, life, environment, diagenesis/lithification, and contemporaneous tecto- nism also have significant influences on sediment composition/geochemistry along the way from source to sink. The recent special issue of Earth Science Reviews (Walsh et al., 2016) presents several interesting recent to Miocene S2S sediment provenance studies on SedimentProvenance http://dx.doi.org/10.1016/B978-0-12-803386-9.00001-0 1 Copyright©2017ElsevierInc.Allrightsreserved. 2 1. SEDIMENTPROVENANCE:INFLUENCEONCOMPOSITIONALCHANGEFROMSOURCETOSINK differentcontinents.OneofthecriticalareasthatdeservescloserscrutinybytheS2Scommu- nity is linking the present and the past (Walsh et al., 2016). As pointed out by Walsh et al. (2016), “there continues to be too much community disconnect among ‘modern’ (process), Quaternary and deep-time researchers.” It must be noted that researchers have undertaken provenanceanalysisofmucholder(asoldasearlyArchean)sedimentarydepositsofthema- jor cratonic blocks of the world, including those of Antarctica and Greenland (see Eriksson et al., 2004 and references therein). In spite of significant technological development and consequentscientific advancementin last 20years, there isalmost no memoir/specialpubli- cation/book that treats sedimentary rocks from an S2S perspective. This book provides a critical and comprehensive overview as well as new data-based sediment provenance analyses from Precambrian to recent from several continents and will fill in the gap in the knowledge base. The content of the book has been divided into 19 chapters. The first (Basu) is a critical appraisal of the conceptual evolution and the enhanced scope of inquiries into the prove- nance of siliciclastic sediments. Van Loon et al. have traced the source of bio/siliciclastic beach sands of the Apulian Coast of Italy. Their analyses reveal a wave-eroded lithified sand source for the beach sands and contribution from a wide variety of organisms. Van _ Loon and Pisarska-Jamrozy have undertaken a detailed heavy mineral study of Pleistocene sandurs, ice-marginal valley and a nearby river in Poland, and have shown that heavy mineralanalysescansignificantlycontributetothereconstructionofthepathwayofsedimen- tary particles and of the changes in the heavy-mineral spectra from source to sink. The hydraulic conditions prevailing during sediment transportation have the prime control on sedimentdispersalpatterns,andthushaveasignificantinfluenceonthechangesinsediment composition during the journey from source to sink. Dasgupta has critically reviewed the problematic aspects of paleohydraulic parameter reconstructions from primary sedimentary structures and believes that quantitative methodology for the precise estimation of paleohy- draulicparametersfromdepositionalsedimentarystructures“isyettobedevelopedthrough systematic laboratory and field experiments that can be repeated and empirically verified.” Sedimentological analysis of the Lower Cretaceous siliciclastic rocks (sandstones) of the Pondicherryembryonicriftbasin,IndiabySarkaretal.clearlyrevealscratonicsourcegaining relative maturity toward the distal depositional setting. Variable degrees of mixing of felsic andmaficcomponents andsource-shiftingasaconsequence ofriftinghavebeenestablished by these authors. Nagarajan et al. have undertaken petrographic and geochemical analyses of Neogene Sibuti and Lambir formations, east Malaysia (Borneo). Their research indicates derivation of sediments from recycled felsic provenance in a predominantly continental to passive margin setting associated with rifting of the proto-South China Sea during the early to middle Miocene. The origin of “V”-shaped elongated dune complexes of Madagascar (Chevron complexes) is disputed; Abbott et al. have argued against the Aeolian origin of these dune complexes. Their sedimentological (grain-size), micropaleontological, and geochronological data from three dune complexes of Madagascar indicate these dune complexes are the depositional product of a Holocene megatsunami possibly related to a Holocenelandslide,orbolideimpact(Abbottetal.).Manyfundamentalproblemsofcontour- ite research have been pointed out by Shanmugam in his detailed and critical review. The contourite domain, according to Shanmugam, is “still in a state of flux after nearly 60years of research” because of those fundamental problems. 3 1. SEDIMENTPROVENANCE:INFLUENCEONCOMPOSITIONALCHANGEFROMSOURCETOSINK Continentalsequencesgenerallyrecordastronginfluenceofsedimentsourceondeposi- tional facies and provide excellent opportunities for S2S analyses. Sato and Chan have un- dertaken a detailed sedimentological analysis of the Eocene Duchesne River formation of the Uinta Basin, Utah, USA, and have demonstrated how different source inputs control sedimentary facies development and sandstone petrophysical properties in the sink. Their study reveals the importance of sediment provenance analysis for exploration of fluvial sandstone reservoirs. Van Loon et al. have examined a series of lenses of limestone breccia from the Late Cambrian (Furongian) Chaomidian Formation in Shandong Province, China and interpreted these as a consequence of fragmentation followed by sliding of a breccia layerfromtheparentlayer(thesource)toitsdepositionalsite(thesink).Longhasexamined cherts of Upper Jurassic to Lower Cretaceous Tantalus Formation, in south-central Yukon, Canada.HisstudyrevealsthatalargeslabofCacheCreekwasobductedoverstrataofthe YukoneTanana terrane, and this now eroded slab was the source of chert in the Tantalus piggyback basins. Late Neoproterozoic to early Mesozoic sedimentary succession of the Tasmanides of eastern Australia developed in an active plate margin setting. Multidisciplinary research undertaken by Fergusson revels provenance switching between the developments of igneous-dominated detritus related to adjoining magmatic arcs (e.g., the Macquarie Arc), and interactions with Gondwana-derived clastics. Chiarenzelli utilized detrital zircons in anupperamphibolitefaciesterraintodocumentsedimentprovenanceandbasinevolution, and to provide initial temporal constraints on sedimentation. Das et al. have presented detrital records of sediment provenance and its shift in the Mesoproterozoic Singhora Group, central India. Sengupta et al. inferred sedimentary provenance, timing of sedimen- tation,andmetamorphismfromasuiteofmetapelitesfromtheChotanagpurGraniteGneiss Complex, eastern India, and discussed their implications for Proterozoic tectonics in the east-centralpartoftheIndianshield.Mukhopadhayaetal.haveundertakenSEMeCLfab- ric analysis of quartz framework population from the Mesoarchean Keonjhar Quartzite fromSinghbhumCraton,easternIndia.Theseauthorshavediscussedimplicationsofprov- enance analysis for the upper continental crustal evolution. Costa and Hofmann have undertaken provenance analysis of detrital pyrite in the Mesoarchaean Witwatersrand BasinofSouthAfrica,theworld’slargestgolddeposit.Accordingtotheseauthors,detrital pyrite is mainly derived from sedimentary sources and syn-sedimentary precipitates. Young has discussed the ice ages in earth history, “puzzling” paleolatitudes, and regional provenance of the ice sheets. According to Young, “the evolution of metazoans, climaxing with the ‘Cambrian explosion,’ may have been accelerated by rapid and radical environ- mental changes associated with glaciations.” The world’s oldest sedimentary structures are preserved in dolomitic carbonates, banded iron formations, volcaniclastic sedimentary rocks, and very rare sandstones and conglomerates in the 3.7e3.8billion years old Isua supracrustal belt in North Atlantic craton (Greenland). The holistic appraisal of the Isua supracrustals by Nutman et al. indicates they formed over a 100-million-year period in supra-subduction zone settings. I strongly believe that a state-of-the art exposition of sediment provenance analyses will helptoidentifykeyissuesandgapsintheexistingknowledgebaseandinitiatenewresearch to understand source rock characteristics, paleoweathering, paleoclimate, tectonics, and ultimately, the evolution of continental crust. 4 1. SEDIMENTPROVENANCE:INFLUENCEONCOMPOSITIONALCHANGEFROMSOURCETOSINK Acknowledgment Iamgratefultoallcontributors,reviewers,andcolleaguesatElsevier,especiallyTashaFrankandMarisaLaFleur, who supported me in various ways. I gratefully acknowledge infrastructural support provided by the Faculty of EngineeringandScience,CurtinUniversity,Sarawak,Malaysia.ProfessorsKennethEriksson,PatrickG.Eriksson, andChristopherFedocriticallycommentedontheoriginalbookproposalandhelpedmetoorganizethebook. References Bhattacharya,J.P.,Copeland,P.,Lawton,T.F.,Holbrook,J.,2016.Estimationofsourcearea,riverpaleo-discharge, paleoslope, and sediment budgets of linked deep-time depositional systems and implications for hydrocarbon potential.EarthScienceReviews153,77e110. EduardoGarzanti,E.,Vermeesch,P.,Padoan,M.,Resentini,A.,Vezzoli,G.,Andò,S.,2014.Provenanceofpassive- marginsand(SouthernAfrica).JournalofGeology122,17e42. Eriksson,P.G.,Altermann,W.,Nelson,D.R.,Mueller,W.,Catuneanu,O.,2004.ThePrecambrianEarth,Temposand Events.ElsevierScience,966p. Haughton, P.D., Todd, S.P., Morton, A.C., 1991. Sedimentary provenance studies. In: Morton, A.C., Todd, S.P., Haughton, P.D.W. (Eds.), Developments in Sedimentary Provenance Studies, 57. Geological Society Special PublicationNo,pp.1e11. Wals,J.P.,Wiberg,P.L.,Aalto,R.,Nittrouer,C.A.,Kuehl,S.A.,2016.Source-to-sinkresearch:economyoftheEarth’s surfaceanditsstrata.EarthScienceReviews153,1e6. Weltje,G.J.,VonEynatten,H.,2004.Quantitativeprovenanceanalysisofsediments:reviewandoutlook.Sedimen- taryGeology171,1e11. C H A P T E R 2 Evolution of Siliciclastic Provenance Inquiries: A Critical Appraisal A. Basu Indiana University, Bloomington, IN, United States O U T L I N E 1. Introduction 5 5.2 Bulk Chemical Compositions 14 5.3 Properties of Single Minerals 15 2. Purpose and Scope 6 6. Discussion 16 3. Materials and Relevant Properties 7 7. The Future 17 4. Investigative Techniques and Insightful Results 8 8. Conclusions 17 4.1 Optical Microscopy 8 Acknowledgments 18 4.2 Chemical Compositions of Bulk Rocks 9 References 18 4.3 Populations of Single Derital Appendix I. Diverse Criteria for Minerals 10 Modal Analysis of Sandstones 23 5. The Critique 13 5.1 Bulk Mineralogical Compositions 13 1. INTRODUCTION Curiosity about origin is a fundamental human urge. Investigating the provenance of sil- iciclasticdebrisandrocksisasubsetofthatcuriosity.HenryCliftonSorbysagaciouslydeter- mined, morethan 150yearsago, onthebasisofoptical petrography, that thequartzarenitic SedimentProvenance http://dx.doi.org/10.1016/B978-0-12-803386-9.00002-2 5 Copyright©2017ElsevierInc.Allrightsreserved.