Abstract
Three triggering factors, including preservation, organic paleoproductivity, and clastic dilution, for the formation of black shale successions during the Ordovician-Silurian transition have been debated for many years. Preserving conditions are controlled by redox conditions and microbial activities which have close relationship with salinity. Five outcrop sites of the Wufeng-Longmaxi black shales located in the southeastern area of Chongqing are analyzed for their elemental geochemistry, total organic carbon, and clay minerals. Clay minerals and boron are used to reconstruct the paleosalinity (S p) of the bottom water during this period. Depending on the clay minerals’ specific combining pattern, the calculation of S p is modified. The results show that the S p concentration ranges from 1.73 to 16.12 ‰, with an average value of 9.68 ‰. This shows an increasing trend from the Late Ordovician to the Early Silurian, indicating oligohaline-mesohaline water. Desalinization of the global ocean in the Late Ordovician was caused by melting of continental glaciers. The S p concentration shows negative correlation with total organic carbon (TOC) content, since the microbial decomposition rates are improved by high salinity. V/(V + Ni) and V/Cr ratios are used to reconstruct the paleoredox conditions of the bottom seawater during the Ordovician-Silurian transition, and the results suggest that the oxygen levels in seawater increased from the Late Ordovician to the Early Silurian and increased landward as a whole. Correlation between redox conditions with the TOC content reveals that anoxic conditions are favorable to the accumulation of organic matter. Ba and (Ba/Al)terr are used to calculate the biogenic Ba, in order to reconstruct organic paleoproductivity. The biogenic Ba shows no apparent relationship with the TOC content, which implies that organic paleoproductivity does not solely control the accumulation of organic matter. Si/Al and Ti/Al ratios are considered as indicators of clastic input. Our data imply that clastic input is quite low in the distal basin around the Ordovician-Silurian boundary, which is consistent with the maximum content of TOC. In the proximal basin, high clastic input dilutes enrichment of organic matter. We may conclude that complex, non-linear interactions among the three factors most likely lead to the accumulation of organic matter. High preservation, low dilution, and low organic production lead to the formation of organic-rich shale, whereas low preservation, high dilution, and high organic production lead to organic-poor shale.
Key Points
Paleoenvironment and organic paleoproductivity of the Yangtze Platform during the Late Ordovician and the Early Silurian are reconstructed.
A combination of multiple factors significantly affects the formation of organic-rich shales.
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References
Adams T, Haynes J, Walker C (1965) Boron in Holocene illites of the dovey estuary, wales, and its relationship to palaeosalinity in cyclothems. Sedimentology 4:189–195
Arthur MA (2005) Sea-level control on source-rock development: perspectives from the Holocene Black Sea, the mid-Cretaceous Western Interior Basin of North America, and the Late Devonian Appalachian Basin. In: Harris NB (ed) The Deposition of Organic-Carbon-Rich Sediments: Models, Mechanisms, and Consequences. Society for Sedimentary Geology (SEPM) Tulsa, Oklahoma, USA, pp 35–39
Bender M, Jahnke R, Ray W, Martin W, Heggie DT, Orchardo J, Sowers T (1989) Organic carbon oxidation and benthic nitrogen and silica dynamics in San Clemente Basin, a continental borderland site. Geochim Cosmochim Acta 53:685–697
Berger W (1979) Impact of deep‐sea drilling on paleoceanography. In: Manik Talwani WH, William B, Ryan F (ed) Deep Drilling Results in the Atlantic Ocean: Continental Margins and Paleoenvironment. American Geophysical Union, pp 297–314
Bertrand P, Shimmield G, Martinez P, Grousset F, Jorissen F, Paterne M, Pujol C, Bouloubassi I, Menard PB, Peypouquet J-P (1996) The glacial ocean productivity hypothesis: the importance of regional temporal and spatial studies. Mar Geol 130:1–9
Bohacs KM (2005) Production, destruction, and dilution—the many paths to source-rock development. In: Harris NB (ed) The Deposition of Organic-Carbon-Rich Sediments: Models, Mechanisms, andConsequences. Society fo Sedimentary Geology, Tulsa, Oklahoma, USA, pp 61–101
Bohor B, Gluskoter HJ (1973) Boron in illite as an indicator of paleosalinity of Illinois coals. J Sediment Res 43:945–956
Brumsack H-J (2006) The trace metal content of recent organic carbon-rich sediments: implications for Cretaceous black shale formation. Palaeogeogr Palaeoclimatol Palaeoecol 232:344–361
Calvert S (1987) Oceanographic controls on the accumulation of organic matter in marine sediments. Geol Soc Lond Spec Publ 26:137–151
Canfield DE (1989) Sulfate reduction and oxic respiration in marine sediments: implications for organic carbon preservation in euxinic environments. Deep sea research part A. Oceanogr Res Pap 36:121–138
Chen X, Rong JY, Zhou ZY (2001) Qianzhong upheaval and Yichang rise formed at transition between the Ordovician and Silurian in upper Yangtze region. Chin Sci Bull 46:1052–1056
Cocks L (2001) Ordovician and Silurian global geography presidential address, delivered 3 May 2000. J Geol Soc 158:197–210
Cook PJ (1977) Loss of boron from shells during weathering and possible implications for the determination of palaeosalinity. Nature 268:426–427
Couch EL (1971) Calculation of paleosalinities from boron and clay mineral data. AAPG Bull 55:1829–1837
Craft C (2007) Freshwater input structures soil properties, vertical accretion, and nutrient accumulation of Georgia and US tidal marshes. Limnol Oceanogr 52:1220–1230
Creaney S, Passey QR (1993) Recurring patterns of total organic carbon and source rock quality within a sequence stratigraphic framework. Aapg Bull 77:386–401
Curtis C (1964) Studies on the use of boron as a paleoenvironmental indicator. Geochim Cosmochim Acta 28:1125–1137
Demaison G, Moore G (1980) Anoxic environments and oil source bed genesis. Org Geochem 2:9–31
Dymond J, Suess E, Lyle M (1992) Barium in deep‐sea sediment: a geochemical proxy for paleoproductivity. Paleoceanography 7:163–181
Francois R, Honjo S, Manganini SJ, Ravizza GE (1995) Biogenic barium fluxes to the deep sea: implications for paleoproductivity reconstruction. Glob Biogeochem Cycles 9:289–303
Funnell B (1987) Anoxic non-events; alternative explanations. Geol Soc Lond, Spec Publ 26:421–422
Goldberg ED, GOS A (1958) Chemistry of Pacific pelagic sediments. Geochim Cosmochim Acta 13:153–212
Goodarzi F, Swaine D (1994) The influence of geological factors on the concentration of boron in Australian and Canadian coals. Chem Geol 118:301–318
Hatch J, Leventhal J (1992) Relationship between inferred redox potential of the depositional environment and geochemistry of the Upper Pennsylvanian (Missourian) Stark Shale Member of the Dennis Limestone, Wabaunsee County, Kansas, USA. Chem Geol 99:65–82
Hower JC, Ruppert LF, Williams DA (2002) Controls on boron and germanium distribution in the low-sulfur Amos coal bed, Western Kentucky coalfield, USA. Int J Coal Geol 53:27–42
Jones B, Manning DA (1994) Comparison of geochemical indices used for the interpretation of palaeoredox conditions in ancient mudstones. Chem Geol 111:111–129
Keith M, Degens E (1959) Geochemical indicators of marine and fresh water sediments. Res Geochem 1:38–61
Lerman A (1966) Boron in clays and estimation of paleosalinities. Sedimentology 6:267–286
Levinson A, Ludwick JC (1966) Speculation on the incorporation of boron into argillaceous sediments. Geochim Cosmochim Acta 30:855–861
Lewan MD (1984) Factors controlling the proportionality of vanadium to nickel in crude oils. Geochim Cosmochim Acta 48:2231–2238
Li J, Servais T, Yan K, Zhu H (2004) A nearshore–offshore trend in acritarch distribution from the Early–Middle Ordovician of the Yangtze Platform, South China. Rev Palaeobot Palynol 130:141–161
Li J, Xu B-S, Liu C, Sun M-D (2012a) Clay minerals of black shale and their effects on physical properties of shale gas reservoirs in the southeast of Chongqing: a case study from Lujiao outcrop section in Pengshui, Chongqing. Geoscience 26:732–740
Li YF, Fan TL, Gao ZQ, Zhang JC, Wang XM, Zeng WT, Zhang JP (2012b) Sequence stratigraphy of Silurian black shale and its distribution in the southeast area of Chongqing. Nat Gas Geosci (In Chin) 23:299–306
Liu BJ, Xu X, Pan XG et al (1993) Evolution and minerals of sedimentary earth in south. Science Press, Beijing
Martínek K, Blecha M, Daněk V, Franců J, Hladíková J, Johnová R, Uličný D (2006) Record of palaeoenvironmental changes in a Lower Permian organic-rich lacustrine succession: integrated sedimentological and geochemical study of the Rudník member, Krkonoše Piedmont Basin, Czech Republic. Palaeogeogr Palaeoclimatol Palaeoecol 230:85–128
McManus J, Berelson WM, Klinkhammer GP, Johnson KS, Coale KH, Anderson RF, Kumar N, Burdige DJ, Hammond DE, Brumsack HJ (1998) Geochemistry of barium in marine sediments: implications for its use as a paleoproxy. Geochim Cosmochim Acta 62:3453–3473
Melchin MJ, Mitchell CE, Holmden C, Storch P (2013) Environmental changes in the Late Ordovician-early Silurian: Review and new insights from black shales and nitrogen isotopes. Geol Soc Am Bull 125(11–12):1635–1670
Metcalfe I (1994) Late Palaeozoic and Mesozoic palaeogeography of eastern Pangea and Tethys. In: Embry AF, Beauchamp B, Glass DJ (ed) Pangea: Global Environments and Resources. CanadianSociety of Petroleum Geologists, pp 97–111
Metcalfe I (2006) Palaeozoic and Mesozoic tectonic evolution and palaeogeography of East Asian crustal fragments: the Korean Peninsula in context. Gondwana Res 9:24–46
Metcalfe I (2013) Gondwana dispersion and Asian accretion: tectonic and palaeogeographic evolution of eastern Tethys. J Asian Earth Sci 66:1–33
Morris R (1987) The formation of organic-rich deposits in two deep-water marine environments. Geol Soc Lond, Spec Publ 26:153–166
Morrissey EM, Gillespie JL, Morina JC, Franklin RB (2014) Salinity affects microbial activity and soil organic matter content in tidal wetlands. Glob Chang Biol 20:1351–1362
Murphy AE, Sageman BB, Hollander DJ, Lyons TW, Brett CE (2000) Black shale deposition and faunal overturn in the Devonian Appalachian Basin: clastic starvation, seasonal water‐column mixing, and efficient biolimiting nutrient recycling. Paleoceanography 15:280–291
Oertli H (1964) The Venice System for the classification of marine waters according to salinity. Pubbli Stn Zool Napoli 33:611
Paropkari AL, Prakash Babu C, Mascarenhas A (1992) A critical evaluation of depositional parameters controlling the variability of organic carbon in Arabian Sea sediments. Mar Geol 107:213–226
Perry EA (1972) Diagenesis and validity of boron paleosalinity technique. Am J Sci 272:150–160
Pfeifer K, Kasten S, Hensen C, Schulz HD (2001) Reconstruction of primary productivity from the barium contents in surface sediments of the South Atlantic Ocean. Mar Geol 177:13–24
Rimmer SM, Thompson JA, Goodnight SA, Robl TL (2004) Multiple controls on the preservation of organic matter in Devonian–Mississippian marine black shales: geochemical and petrographic evidence. Palaeogeogr Palaeoclimatol Palaeoecol 215:125–154
Roopnarine PD, Fitzgerald P, Byars G, Kilb K (1998) Coincident boron profiles of bivalves from the Gulf of California; implications for the calculation of paleosalinities. Palaios 13:395–400
Rösler HJ, Lange H, Liebscher H (1972) Geochemical tables. Elsevier, Amsterdam
Sageman BB, Murphy AE, Werne JP, Ver Straeten CA, Hollander DJ, Lyons TW (2003) A tale of shales: the relative roles of production, decomposition, and dilution in the accumulation of organic-rich strata, Middle–Upper Devonian, Appalachian basin. Chem Geol 195:229–273
Schieber J (1996) Early diagenetic silica deposition in algal cysts and spores: a source of sand in black shales? J Sediment Res 66:175–183
Schieber J (1998) Possible indicators of microbial mat deposits in shales and sandstones: examples from the Mid-Proterozoic Belt Supergroup, Montana, USA. Sediment Geol 120:105–124
Środoń J, Paszkowski M (2011) Role of clays in the diagenetic history of nitrogen and boron in the Carboniferous of Donbas (Ukraine). Clay Miner 46:561–582
Stow D, Huc AY, Bertrand P (2001) Depositional processes of black shales in deep water. Mar Petrol Geol 18:491–498
Taylor S (1964) Abundance of chemical elements in the continental crust: a new table. Geochim Cosmochim Acta 28:1273–1285
Torres M, Brumsack H, Bohrmann G, Emeis K (1996) Barite fronts in continental margin sediments: a new look at barium remobilization in the zone of sulfate reduction and formation of heavy barites in diagenetic fronts. Chem Geol 127:125–139
Tribovillard N, Algeo TJ, Lyons T, Riboulleau A (2006) Trace metals as paleoredox and paleoproductivity proxies: an update. Chem Geol 232:12–32
Tyson R (1987) The genesis and palynofacies characteristics of marine petroleum source rocks. Geol Soc Lond, Spec Publ 26:47–67
Tyson RV (2001) Sedimentation rate, dilution, preservation and total organic carbon: some results of a modelling study. Org Geochem 32:333–339
Tyson R (2005) The “productivity versus preservation” controversy: cause, flaws, and resolution. Spec Publ-SEPM 82:17
van Os BJ, Middelburg JJ, de Lange GJ (1991) Possible diagenetic mobilization of barium in sapropelic sediment from the eastern Mediterranean. Mar Geol 100:125–136
Van Santvoort P, De Lange G, Thomson J, Cussen H, Wilson T, Krom M, Ströhle K (1996) Active post-depositional oxidation of the most recent sapropel (S1) in sediments of the eastern Mediterranean Sea. Geochim Cosmochim Acta 60:4007–4024
Wadhams P (2004) Ocean freshening, sea level rising, sea ice melting. Geophys Res Lett 31:1–4
Walker CT, Price NB (1963) Departure curves for computing paleosalinity from boron in illites and shale. AAPG Bull 47:833–841
Wang G (2000) Petrpleum exploration in the marine strata in southern China-exploration situation and proposal. Acta Pet Sin 21(5):1–6
Wang G, Carr TR (2013) Organic-rich Marcellus Shale lithofacies modeling and distribution pattern analysis in the Appalachian Basin. AAPG Bull 97:2173–2205
Werne JP, Sageman BB, Lyons TW, Hollander DJ (2002) An integrated assessment of a “type euxinic” deposit: evidence for multiple controls on black shale deposition in the Middle Devonian Oatka Creek Formation. Am J Sci 302:110–143
Wignall PB (1991) Model for transgressive black shales? Geology 19:167–170
Wignall PB (1994) Black shales. Clarendon, Oxford
Woolnough WG (1937) Sedimentation in barred basins, and source rocks of oil. AAPG Bull 21:1101–1157
Yan D, Chen D, Wang Q, Wang J (2009a) Geochemical changes across the Ordovician-Silurian transition on the Yangtze Platform, South China. Sci China Ser D Earth Sci 52:38–54
Yan D, Chen D, Wang Q, Wang J, Wang Z (2009b) Carbon and sulfur isotopic anomalies across the Ordovician–Silurian boundary on the Yangtze Platform, South China. Palaeogeogr Palaeoclimatol Palaeoecol 274:32–39
Yan D, Chen D, Wang Q, Wang J (2010) Large-scale climatic fluctuations in the latest Ordovician on the Yangtze block, south China. Geology 38:599–602
Yan D, Chen D, Wang Q, Wang J (2012) Predominance of stratified anoxic Yangtze Sea interrupted by short-term oxygenation during the Ordo-Silurian transition. Chem Geol 291:69–78
Zhang T, Kershaw S, Wan Y, Lan G (2000) Geochemical and facies evidence for palaeoenvironmental change during the Late Ordovician Hirnantian glaciation in south Sichuan Province, China. Glob Planet Chang 24:133–152
Zhou MK, Wang RZ, Li ZM et al (1993) Ordovician and Silurian lithofacies palaeogeography and mineralization in south China. Geological Publishing House, Beijing
Acknowledgments
This study is financially supported by the National Key Project of China (2009GYXQ15-04) and China Scholarship Council (CSC). We thank Dr. David Riese at Shell Oil Company, Dr. David L. Dilcher, and Mrs. Doris Zakian at Indiana University Bloomington for polishing our writing. We thank anonymous reviewers for their critical comments, which were very helpful to improve the manuscript. Thanks also go to Associate Editor Issa Makhlouf and Editor-in-Chief Abdullah M. Al-Amri for their editorial help and comments.
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Li, Y., Fan, T., Zhang, J. et al. Impact of paleoenvironment, organic paleoproductivity, and clastic dilution on the formation of organic-rich shales: a case study about the Ordovician-Silurian black shales, southeastern Chongqing, South China. Arab J Geosci 8, 10225–10239 (2015). https://doi.org/10.1007/s12517-015-1944-y
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DOI: https://doi.org/10.1007/s12517-015-1944-y