Abstract
Early Eocene lignite-bearing sequence from Cambay Basin was characterized by means of petrographic and organic geochemical analyses in order to assess its hydrocarbon-generating potential as well as reconstruct the palaeovegetation and palaeoenvironment. Huminite is the most abundant maceral in the samples. Subordinate amount of liptinite and inertinite is also present. The kerogen was classified, based on Rock-Eval and FTIR analyses, as mixed type II/type III with potential to generate both oil and gas upon maturation. The FTIR analysis also indicated abundance of aromatic and phenolic compounds with significant amount of aliphatic components. n–Alkanes present in the lignite samples ranged from C10 to C35, maximizing at C16, and displayed a bimodal distribution suggesting two different organic matter inputs, viz. microbes and higher plants. The triterpenoid class included ββ–hopane series ranging from C29 to C32, several hopenes, oleanenes, ursenes and some des–A–triterpenoids. The hopanes and hopenes were mainly derived from microbial components. Oleanenes, ursenes and des–A–triterpenoids were primarily derived from precursors β– and α–amyrin suggesting angiosperm contribution. Fernenes identified in the samples probably suggested pteridophytic input. The various petrographic parameters demonstrated the environment of deposition of these lignites as being wet, acidic and swampy.
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References
Prasad V, Farooqui A, Tripathi SKM, Garg R (2009) Evidence of Late Palaeocene-Early Eocene equatorial rain forest refugia in south-western Ghats, India. J Biosci 34:1–21
McGowran B (1989) Silica burp in the Eocene ocean. Geology 17:857–860
Sahni A, Saraswati PK, Rana RS, Kumar K, Singh H, Alimohammadian H, Sahni N, Rose KD, Singh L, Smith T (2006) Temporal constraints and depositional palaeoenvironments of the Vastan Lignite Sequence, Gujarat: Analogy for the Cambay Shale Hydrocarbon Source Rock. Ind J Pet Geol 15:1–20
Ahmed M, Volk H, George SC, Faiz M, Stalker L (2009) Generation and expulsion of oils from Permian coals of the Sydney Basin, Australia. Org Geochem 40:810–831
Brooks JD, Smith JW (1969) The diagenesis of plant lipids during the formation of coal, petroleum and natural gas: II. Coalification and the formation of oil and gas in the Gippsland Basin. Geochim Cosmochim Acta 33:1183–1194
Shanmugam G (1985) Significance of coniferous rain forests and related organic matter in generating commercial quantities of oil, Gippsland Basin, Australia. AAPG Bull 69:1241–1254
Hirner AV, Lyon GL (1989) Stable isotope geochemistry of crude oils and of possible source rocks from New Zealand: 1. Carbon. Appl Geochem 4:109–120
Hirner AV, Robinson BW (1989) Stable isotope geochemistry of crude oils and of possible source rocks from New Zealand: 2. Sulfur. Appl Geochem 4:121–130
Killops SD, Woolhouse AD, Weston RJ, Cook RA (1994) A geochemical appraisal of oil generation in the Taranaki Basin, New Zealand. AAPG Bull 78:1560–1585
Hoffmann CF, Mackenzie AS, Lewis CA, Maxwell JR, Oudin JL, Durand B, Vandenbroucke M (1984) A biological marker study of coals, shales and oils from the Mahakam Delta, Kalimantan, Indonesia. Chem Geol 42:1–23
Horsfield B, Yordy KL, Crelling JC (1988) Determining the petroleum-generating potential of coal using organic geochemistry and organic petrology. Org Geochem 13:121–129
Peters KE, Snedden JW, Sulaeman A, Sarg JE, Enrico RJ (2000) A new geochemical-sequence stratigraphic model for the Mahakam Delta and Makassar Slope, Kalimantan, Indonesia. AAPG Bull 84:12–44
Odden W, Patience RL, van Graas GW (1998) Application of light hydrocarbons (C4-C13) to oil/source rock correlations: a study of the light hydrocarbon compositions of source rocks and test fluids from offshore Mid-Norway. Org Geochem 28:823–847
Petersen HI, Rosenberg P, Andsbjerg J (1996) Organic geochemistry in relation to the depositional environments of Middle Jurassic coal seams, Danish Central Graben, and implications for hydrocarbon generative potential. AAPG Bull 80:47–62
Petersen HI, Andsbjerg J, Bojesen-Koefoed JA, Nytoft HP (2000) Coal-generated oil: source rock evaluation and petroleum geochemistry of the Lulita oilfield, Danish North Sea. J Pet Geol 23:55–90
Petersen HI, Brekke T (2001) Source rock analysis and petroleum geochemistry of the Trym discovery, Norwegian North Sea: A Middle Jurassic coal-sourced petroleum system. Mar Petrol Geol 18:889–908
Hendrix MS, Brassell SC, Carroll AR, Graham SA (1995) Sedimentology, organic geochemistry, and petroleum potential of Jurassic coal measures: Tarim, Junggar, and Turpan Basins, Northwest China. AAPG Bull 79:929–959
Ramaswamy G (2005) Some fields in India’s North Cambay Basin have oil derived from nearby lignite seams. Oil Gas J 103:37–42
Bajpai S, Kay RF, Williams BA, Das DP, Kapur VV, Tiwari BN (2008) The oldest Asian record of Anthropoidea. PNAS 105:11093–11098
Rose KD, DeLeon VB, Missiaen P, Rana RS, Sahni A, Singh L, Smith T (2008) Early Eocene lagomorph (Mammalia) from western India and the early diversification of Lagomorpha. Proc R Soc Lond B 275:1203–1208
Mandal J, Guleria JS (2006) Palynology of Vastan lignite (Surat District), Gujarat: its age, palaeoecology and depositional environment. Palaeobotanist 55:51–66
Garg R, Ateequzzaman K, Singh V, Tripathi SKM, Singh IB, Jauhri AK, Bajpai S (2008) Age-diagnostic dinoflagellate cysts from the lignite-bearing sediments of the Vastan Lignite Mine, Surat District, Gujarat, Western India. J Palaeontol Soc Ind 53:99–105
Clementz M, Bajpai S, Ravikant V, Thewissen JGM, Saravanan N, Singh IB, Prasad V (2010) Early Eocene warming events and the timing of terrestrial faunal exchange between India and Asia. Geology 39:15–18
Punekar J, Saraswati PK (2010) Age of the Vastan lignite in context of some oldest Cenozoic fossil mammals from India. J Geol Soc India 76:63–68
Samanta A, Bera MK, Ghosh R, Bera S, Filley T, Pande K, Rathore SS, Rai J, Sarkar A (2013). Do the large carbon isotopic excursions in terrestrial organic matter across Palaeocene-Eocene boundary in India indicate intensification of tropical precipitation? Palaeogeogr Palaeoclimatol Palaeoecol 387:91–103
ICCP (International Committee for Coal and Organic Petrology). International Handbook of Coal Petrography (1975) Centre National de la Recherche Scientifique (CNRS), Paris, France, 1st suppl. to 2nd edition (1971), 197 pp, 2nd suppl. to 2nd edition, 60 pp
Stach E, Mackowsk M-Th, Teichmüller M, Taylor GH, Chandra D, Teichmüller R (1982) Stach’s Textbook of Coal Petrology, 3rd edn. GebrüderBorntraeger, Berlin, p 535
Sýkorová I, Pickel W, Christanis K, Wolf M, Taylor GH, Flores D (2005) Classification of huminite—ICCP System. Int J Coal Geol 62:85–106
Lafargue E, Marquis F, Pillot D (1998) Rock-Eval 6 applications in hydrocarbon exploration, production and soil contamination studies. Oil Gas Sci Technol 53:421–437
Painter P, Starsinic M, Coleman M (1985) Determination of functional groups in coal by Fourier Transform Interferometry. In: Ferraro JR, Basile LJ (eds) Fourier transform infrared spectroscopy, vol. 4. applications to chemical systems, pp 169–241
Dutta S, Hartkopf-Fröder C, Witte K, Brocke R, Mann U (2013) Molecular characterization of fossil palynomorphs by transmission micro-FTIR spectroscopy: Implications for hydrocarbon source evaluation. Int J Coal Geol 115:13–23
Singh PK, Singh MP, Singh AK (2010) Petro-chemical characterization and evolution of Vastan lignite, Gujarat, India. Int J Coal Geol 82:1–16
Dutta S, Mallick M, Bertram N, Greenwood PF, Mathews RP (2009) Terpenoid composition and class of Tertiary resins from India. Int J Coal Geol 80:44–50
Dutta S, Tripathi SM, Mallick M, Mathews RP, Greenwood PF, Rao MR, Summons R (2011) Eocene out-of-India dispersal of Asian dipterocarps. Rev PalaeobotPalynol 166:63–68
Mallick M, Dutta S, Greenwood PF, Bertram N (2009) Pyrolytic and spectroscopic studies of Eocene resin from Vastan lignite mine, Cambay Basin, western India. J Geol Soc India 74:16–22
Taylor GH, Teichmüller M, Davis A, Diessel CFK, Littke R, Robert P (1998) Organic Petrology. GebrüderBorntraeger, Berlin and Stuttgart
Guo Y, Bustin RM (1998) Micro-FTIR spectroscopy of liptinite macerals in coal. Int J Coal Geol 36:259–275
Guo Y, Renton JJ, Penn JH (1996) FTIR microspectroscopy of particular liptinite-(lopinite) rich, Late Permian coals from southern China. Int J Coal Geol 29:187–197
Peters KE, Walters CC, Moldowan JM (2005) The biomarker guide. Volume 2: biomarkers and isotopes in the petroleum exploration and earth history, 2nd edn. Cambridge University Press, Cambridge, UK
Powell TG, McKirdy DM (1973) Relationship between ratio of pristane to phytane, crude oil composition and geological environment in Australia. Nature 243:37–39
Schmitter JM, Sucrow W, Arpino PJ (1982) Occurrence of novel tetracyclic geochemical markers: 8, 14-secohopanes in a Nigerian crude oil. Geochim Cosmochim Acta 46:2345–2350
Ageta H, Shiojima K, Arai Y (1987) Acid-induced rearrangement of triterpenoid hydrocarbons belonging to the hopane and migrated hopane series. Chem Pharm Bull 35:2705–2716
Moldowan JM, Fago FJ, Carlson RMK, Young DC, van Duyne G, Clardy J, Schoell M, Pillinger CT, Watt DS (1991) Rearranged hopanes in sediment sand petroleum. Geochim Cosmochim Acta 55:3333–3353
Rullkötter J, Peakman TM, ten Haven HL (1994) Early diagenesis of terrigenous terpenoids and its implications for petroleum geochemistry. Org Geochem 21:215–223
ten Haven HL, Peakman TM, Rullkötter J (1992) ∆2-Triterpenes: Early intermediates in the diagenesis of terrigenous triterpenoids. Geochim Cosmochim Acta 56:1993–2000
Schmitter JM, Arpino PJ, Guiochon G (1981) Isolation of degraded pentacyclic triterpenoid acids in a Nigerian crude oil and their identification as tetracyclic carboxylic acids resulting from ring A cleavage. Geochim Cosmochim Acta 45:1951–1955
Pearson MJ, Alam M (1993) Bicadinanes and other terrestrial terpenoids in immature Oligocene sedimentary rocks and a related oil from the Surma Basin, N.E. Bangladesh. Org Geochem 20:539–554
Stout SA (1992) Aliphatic and aromatic triterpenoid hydrocarbons in Tertiary angiospermous lignite. Org Geochem 18:51–66
Corbet B, Albrecht P, Ourisson G (1980) Photochemical or photometric fossil triterpenoids in sediments and petroleum. J Am Chem Soc 102:1171–1173
Ganz H, Kalkreuth W (1987) Application of infrared spectroscopy to the classification of kerogen-types and the evolution of source rock and oil-shale potentials. Fuel 66:708–711
Hunt JH (1991) Generation of gas and oil from coal and other terrestrial organic matter. Org Geochem 17:673–680
Mukhopadhyay PK, Hatcher PG (1993) Composition of coal. In: Law BE, Rice DD (eds) Hydrocarbons from Coal, vol 38. American Association of Petroleum Geologists, pp 79–118
Killops SD, Funnell RH, Suggate RP, Sykes R, Peters KE, Walters C, Woolhouse AD, Weston RJ, Boudou J-P (1998) Predicting generation and expulsion of paraffinic oil from vitrinite-rich coals. Org Geochem 29:1–21
Newman J, Price LC, Johnston JH (1997) Hydrocarbon source potential and maturation in Eocene New Zealand vitrinite-rich coals. J Pet Geol 20:137–163
Cranwell PA (1977) Organic geochemistry of CamLoch (Sutherland) sediments. Chem Geol 20:205–221
Cranwell PA (1984) Lipid geochemistry of sediments from Upton Broad, a small productive lake. Org Geochem 7(1):25–37
Kuhn TK, Krull ES, Bowater A, Grice K, Gleixner G (2010) The occurrence of short chain n-alkanes with an even over odd predominance in higher plants and soils. Org Geochem 41:88–95
Bechtel A, Sachsenhofer RF, Kolcon I, Gratzer R, Otto A, Püttmann W (2002) Organic geochemistry of the Lower Miocene Oberdorf lignite (Styrian Basin, Austria): its relation to petrography, palynology and the paleoenvironment. Int J Coal Geol 51:31–57
del Rio JC, Gonzalez-Vila FJ, Martin F (1992) Variation in the content and distribution of biomarkers in two closely situated peat and lignite deposits. Org Geochem 18:67–78
Seifert WK, Moldowan JM (1980) The effect of thermal stress on source-rock quality as measured by hopane stereochemistry. Phys Chem Earth 12:229–237
Seifert WK, Moldowan JM (1986) Use of biological markers in petroleum exploration. In: Johns RB (ed) Methods in Geochemistry and Geophysics, vol 24, pp 261–290
Nott CJ, Xie S, Avsejs LA, Maddy D, Chambers FM, Evershed RP (2000) n-Alkane distributions in ombrotrophic mires as indicators of vegetation change related to climatic variation. Org Geochem 31:231–235
Ficken KJ, Li B, Swain DL, Eglinton G (2000) An n-alkane proxy for the sedimentary input of submerged/floating freshwater aquatic macrophytes. Org Geochem 31:745–749
Hunt JM (1995) Petroleum geochemistry and geology. W.H. Freeman, New York
Cranwell PA (1973) Chain-length distribution of n-alkanes from lake sediments in relation to post-glacial environmental change. Freshwater Biol 3:259–265
Raymond A, Phillips MK, Gennett JA, Comet PA (1997) Palynology and paleoecology of lignites from the Manning Formation (Jackson Group) outcrop in the Lake Somerville spillway of east-central Texas. Int J Coal Geol 34:195–223
Hauke V, Graff R, Wehrung P, Trendel JM, Albrecht P, Riva A, Hopfgartner G, Gülacar FO, Buchs A, Eakin PA (1992) Novel triterpene-derived hydrocarbons of the arborane/ fernane series in sediments: Part II. Geochim Cosmochim Acta 56:3595–3602
Ageta H, Shiojima K, Arai Y (1968) Fern constituents: neohopene, hopene-II, neohopadiene and fernadiene isolated from Adiantum species. J Chem Soc, Chem Commun 1968:1105–1107. https://doi.org/10.1039/C19680001105
Ensminger A, van Dorsselaer A, Spyckerelle C, Albrecht P, Ourisson G (1973) Pentacyclic triterpenes of the hopanetypeas ubiquitous geochemicalmarkers: origin and significance. In: Tissot B, Bienner F (eds) Advances in Organic Geochemistry. Editions Technip, Paris, pp 245–260
Rohmer M, Dastillung M, Ourisson G (1980) Hopanoids from C30 to C35 in recent muds, chemical markers and bacterial activity. Naturewissenschaften 67:456–458
Teichmüller M (1989) The genesis of coal from the view point of coal petrology. Int J Coal Geol 12:1–87
Mackenzie AS, Patience RL, Maxwell JR (1981) Molecular changes and the maturation of sedimentary organic matter. In: Atkinson G, Zuckermann JJ (eds) Origin and chemistry of petroleum. Proc. 3rd Annual Karcher Symposium. Pergamon Press, Oxford, pp 1–31
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CSIR-NGRI, Dr. V.M. Tiwari, Director of CSIR-NGRI, and Dr. E.V.S.S.K. Babu are acknowledged for providing support to M. Mallick. The authors are thankful to IIT Bombay, India, for providing infrastructure.
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Mallick, M., Dutta, S., Singh, B.D., Bhattacharya, S., Singh, A. (2021). Petrographic and Organic Geochemical Characterizations of Early Eocene Lignites, Cambay Basin, Western India. In: Bhui, U.K. (eds) Macromolecular Characterization of Hydrocarbons for Sustainable Future. Green Energy and Technology. Springer, Singapore. https://doi.org/10.1007/978-981-33-6133-1_11
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