Abstract
To understand the distribution regularity of sulfur in coal formed during different geologic periods and their related controlling factors, we obtained statistics on the sulfur content in the coal samples from different regions of the Guangxi Province. Based on the results, we drew the following conclusions. First, the contents of the sulfur forms vary significantly in the coal samples. The sulfide and organic sulfur content account for a relatively high proportion of the total sulfur content while the sulfate sulfur content is relatively low (i.e., 1.29–15.72%, average = 4.83%). Between these factors, the sulfide sulfur content in early Carboniferous coal is slightly higher than the organic sulfur content, while the organic sulfur content in late Permian, Early Jurassic, and Tertiary coal is higher than the sulfide sulfur content, represented by Heshan coal. Second, coals formed in early Carboniferous, late Permian, and Early Jurassic mainly contain high-sulfur coals. In contrast, Neogene coals, with relatively poor sulfur content, are the major source of low-sulfur coals in the Guangxi Province. In this study, the sulfur content in coal formed in early Carboniferous and late Permian is ≥ 4%; thus, this coal belongs to the super-high organic sulfur (SHOS). Finally, we discuss the spatial distribution characteristics of the sulfur content in coals formed during various geologic periods and their controlling factors. The results indicate that the content and form depend on the paleogeographic conditions during the geologic period of formation.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Attar D (1981) Data on the distribution of organic sulfur functional groups in coal. Adv Chem 24:239–256
Bates AL, Spiker EC, Hatcher PG, Stout SA, Weintraub VC (1995) Sulfur geochemistry of organic-rich sediments from Mud Lake, Florida, USA. Chem Geol 121(1–4):245–262
Casagrande DJ, Siefert K, Berschinski C, Sutton N (1977) Sulfur in peat-forming systems of the Okefenokee swamp and Florida everglades: origins of sulfur in coal. Geochim Cosmochim Acta 41(1):161–167
Chen JG, Li YL (1983) The coal-bearing formation and the incoalation model of algal-flat swamps of the Upper Permian in Guangxi. Acta Sedimentol Sin 1(1):86–93
Chen RQ, Wu HO, Long B (1995) Geochemical and chemical constructive characteristics of upper Permian coals in Dongluo Coal Mine, Guangxi. Geotecton Metallog 19(2):145–154
Cheng W, Zhang Q, Yang R, Tian Y (2014) Occurrence modes and cleaning potential of sulfur and some trace elements in a high-sulfur coal from Pu’an Coalfield, SW Guizhou, China. Environ Earth Sci 72(1):35–46
Chou CL (1990) Geochemistry of sulfur in coal. In: Geochemistry of Sulfur in Fossil Fuels, vol 429, pp 30–52
Chou CL, Hackley KC, Cao J (1993) Release of organic, pyritic, elemental, and sulfate sulfur during temperature-programmed pyrolysis of Illinois basin coals. Coal Sci Technol 21(none):15–26
Chou CL (1997) Geologic factors affecting the abundance, distribution and speciation of sulfur in coals. In: Yang Q (ed) Geology of fossil fuels, Proceedings of the 30th International Geological Congress: Part B[C], vol 18. VSP, Utrecht, pp 47–57
Chou CL (2012) Sulfur in coals: a review of geochemistry and origins. Int J Coal Geol 100(none):1–13
Dai SF, Hou XQ, Ren DY, Tang YG (2003) Surface analysis of pyrite in the no. 9 coal seam, Wuda coalfield, Inner Mongolia, China, using high-resolution time-of-flight secondary ion mass-spectrometry. Int J Coal Geol 55(2):139–150
Dai SF, Tian LW, Chou CL, Zhou YP, Zhang MQ, Zhao L, Wang JM, Yang Z, Cao HZ, Ren DY (2008a) Mineralogical and compositional characteristics of late permian coals from an area of high lung cancer rate in Xuan Wei, Yunnan, China: occurrence and origin of quartz and chamosite. Int J Coal Geol 76(4):318–327
Dai SF, Ren DY, Tang YG, Shao LY, Li SS (2002) Distribution, isotopic variation and origin of sulfur in coals in the Wuda coalfield, Inner Mongolia, China. Int J Coal Geol 51(4):237–250
Dai SF, Ren DY, Zhou YP, Chou CL, Wang XB, Zhao L (2008b) Mineralogy and geochemistry of a superhigh-organic-sulfur coal, Yanshan coalfield, Yunnan, China: evidence for a volcanic ash component and influence by submarine exhalation. Chem Geol 255(1–2):0–194
Dai SF, Seredin VV, Ward CR, Hower JC, Xing YW, Zhang WG, Song WJ, Wang PP (2015) Enrichment of U–Se–Mo–Re–V in coals preserved within marine carbonate successions: geochemical and mineralogical data from the Late Permian Guiding Coalfield, Guizhou, China. Mineral Deposita 50(2):159–186
Dai SF, Wang XB, Seredin VV, Hower JC, Ward CR, O’Keefe JMK, Huang WH, Li T, Li X, Liu HD, Xue WF, Zhao LX (2012) Petrology, mineralogy, and geochemistry of the Ge-rich coal from the Wulantuga Ge ore deposit, Inner Mongolia, China: new data and genetic implications. Int J Coal Geol 90-91(1):72–99
Dai SF, Xie PP, French D, Ward CR, Graham IT, Yan XY, Guo WM (2018) The occurrence of buddingtonite in super-high-organic-sulphur coals from the Yishan Coalfield, Guangxi, southern China. Int J Coal Geol 195:347–361
Dai SF, Xie PP, Ward CR, Yan XY, Guo WM, French D, Graham IT (2017) Anomalies of rare metals in Lopingian super-high-organic-sulfur coals from the Yishan Coalfield, Guangxi, China. Ore Geol Rev 88:235–250
Dai SF, Zhang WG, Ward CR, Seredin VV, Hower JC, Li X, Song WJ, Wang XB, Kang H, Zheng LC, Wang PP, Zhou D (2013) Mineralogical and geochemical anomalies of Late Permian coals from the Fusui coalfield, Guangxi Province, southern China: influences of terrigenous materials and hydrothermal fluids. Int J Coal Geol 105(none):60–84
Demir I, Harvey RD (1991) Variation of organic sulfur in macerals of selected Illinois basin coals. Org Geochem 17(4):525–533
Demir I, Harvey RD, Hackley KC (1993) SEM−EDX and isotope characterization of the organic sulfur in macerals and chars in Illinois basin coals. Org Geochem 20(2):257–266
Deng DG, Wu Z (1992) Sedimentary facies characteristics of the early Neogene in Nanning basin, Guangxi. Geol Guangxi 5(2):23–30
Fang SX, Hou FH (1986) The Carboniferous sedimentary environments and the Bryozoan-Coral patch reef of the Datang age of the Langping carbonate platform in Tianlin County, Guangxi Province. Acta Sedimentol Sin 4(3):30–40
Finkelman R, Dai SF, French D (2019) The importance of minerals in coal as the hosts of chemical elements: a review. Int J Coal Geol 212:103251
Finkelman RB, Gross PMK (1999) The types of data needed for assessing the environmental and human health impacts of coal. Int J Coal Geol 40(2):91–101
Francois R (1987) A study of sulphur enrichment in the humic fraction of marine sediments during early diagenesis. Geochim Cosmochim Acta 51(1):17–27
George GN, Gorbaty ML, Kelemen SR, Sansone M (1991) Direct determination and quantification of sulfur forms in coals from the Argonne Premium Sample Program. Energy Fuel 5(1):93–97
Gluskoter HJ (1977) Inorganic sulfur in coal. Energy Sources 3(2):125–131
Hsieh KC, Wert CA (1985) Direct measurement of organic sulphur in coal. Fuel 64(2):255–262
Hsieh KC, Wert CA (1981) Sulfide crystals in coal. Mater Sci Eng 50(1):117–125
Hurley RG, White EW (1974) New soft x-ray method for determining the chemical forms of sulfur in coal. Anal Chem 46(14):2234–2237
Klimont Z, Smith SJ, Cofala J (2013) The last decade of global anthropogenic sulfur dioxide: 2000–2011 emissions. Environ Res Lett 8(1):014003
Kokryatskaya NM, Volkov II, Demidova TP, Murzina TS (2003) Sulfur compounds in bottom sediments of fresh-water basins (mouth of the Severnaya Dvina River and Rybinsk Water Reservoir). Lithol Miner Resour 38(6):552–563
Kuang GD, Chen GJ, Chen YF, Huang ZT (2004) New information on the tertiary biostratigraphy of the Ningming Basin, Guangxi. J Stratigr 28(4):362–366
Lei JJ, Ren DY, Tang YG, Chu XL, Zhao R (1994) Sulfur-accumulating model of superhigh organosulfur coal from Guiding, China. Chin Sci Bull 39(21):1817–1821
Li RG (2007) Coal quality character and its environmental significance in middle part of Yishan coalfield, Guangxi. Coal Geol Chin 19(6):25–28
Li WW, Tang YG (2014) Sulfur isotopic composition of superhigh-organic-sulfur coals from the Chenxi coalfield, southern China. Int J Coal Geol 127:3–13
Li WW, Tang YG, Zhao QJ, Wei Q (2015) Sulfur and nitrogen in the high-sulfur coals of the Late Paleozoic from China. Fuel 155:115–121
Li XC, Liu QL (2019) Simulation research on the interaction between environmental protection investment and economic growth in China. Nat Hazards 95(1–2):257–269
Li ZL (2005) Parallel unconformity of Devonian to early Carboniferous strata in Guangxi. Land Resour South China 11:24–29
Liu GJ (2014a) Lead in Chinese coals: distribution, modes of occurrence, and environmental effects. Environ Geochem Health 36(3):563–581
Liu L (2014b) Research on the Late Triassic to Early Jurassic sedimentary environment and paleogeography of Shiwandashan Basin in Guangxi. China University of Mining and Technology, Xuzhou, pp 37–44
Lu M, Liu W (1999) Sulfur distribution of high sulfur coal and feasibility study of coal desulfurization before combustion. Coal Sci Tech 27(2):42–45
Markic M, Sachsenhofer RF (1997) Petrographic composition and depositional environments of the Pliocene Velenje lignite seam (Slovenia). Int J Coal Geol 33(3):229–254
Mukherjee AB, Zevenhoven R, Bhattacharya P, Saiwan KS, Kikuchi R (2008) Mercury flow via coal and coal utilization by-products: a global perspective. Resour Conserv Recycl 52(4):571–591
Nayak B (2013) Mineral matter and the nature of pyrite in some high-sulfur tertiary coals of Meghalaya, Northeast India. J Geol Soc India 81(2):203–214
Qiu YQ, Mao S, Zhang Q, Tian Y, Liu ZH (2011) Preliminary study on washability and composition analysis of high-sulfur coal in some mining areas in Guizhou. J Coal Sci Eng (China) 17(1):93–95
Raiswell R, Berner RA (1986) Pyrite and organic matter in Phanerozoic normal marine shales. Geochim Cosmochim Acta 50(9):1967–1976
Shao LY, Lu J, Jones T, Gayer R, Shang LJ, Shen ZJ, Zhang PF (2006) Mineralogy and geochemistry of the high-organic sulphur coals from the carbonate coal measures of the Late Permian in Central Guangxi. J China Coal Soc 31(6):770–775
Shao LY, Jones T, Gayer R, Dai SF, Li SS, Jiang YF, Zhang PF (2003) Petrology and geochemistry of the high-sulphur coals from the Upper Permian carbonate coal measures in the Heshan coalfield, southern China. Int J Coal Geol 55(1):1–26
Shao LY, Zhang PF (1999) Lithofacies of the Late Permian submarine fan turbidites in Heshan and Laibin areas, central Guangxi. J Palaeogeogr 1(1):20–31
Siavalas G, Linou M, Chatziapostolou A (2009) Paleoenvironment of seam I in the Marathousa Lignite Mine, Megalopolis Basin (Southern Greece). Int J Coal Geol 78(4):233–248
Spiker EC, Pierce BS, Bates AL, Stanton RW (1994) Isotopic evidence for the source of sulfur in the Upper Freeport coal bed (west-central Pennsylvania, U.S.A.). Chem Geol 114(1–2):0–130
Spiro BF, Liu JJ, Dai SF, Zeng RS, Large D, French D (2019) Marine derived 87Sr/86Sr in coal, a new key to geochronology and palaeoenvironment: elucidation of the India-Eurasia and China-Indochina collisions in Yunnan, China. Int J Coal Geol 215(none):103304
Sprague DD, Vermaire JC (2018) The landscape-scale relationship between lake sediment geochemistry and catchment bedrock composition from the Temagami and Gowganda areas of Northeastern Ontario, Canada. Environ Earth Sci 77(12):463–481
Taylor GH, Mackowskv MT, Davis A (1998) Organic petrology. Gebrider Borntraeger Press, Berlin-Stuttgart
Wang BY, Qin Y, Shen J, Wang G, Li JQ (2018) Formation environment of main brown coal seam in Xi-2 minefield of shengli coalfield based on coal ash phase analysis. J Geol Soc India 92(1):111–119
White D, Thiessen R (1913) The origin of coal. US Government Printing Office
Williams EG, Keith ML (1963) Relationship between sulfur in coals and the occurrence of marine roof beds. Econ Geol 58(5):720–729
Yang YL, Zhao QJ (2018) Analysis of aromatic hydrocarbon in medium-to high sulfur coals from Fenxi, Shanxi province. World J Eng 15(6):786–791
Zaback DA, Pratt LM, Hayes JM (1993) Transport and reduction of sulfate and immobilization of sulfide in marine black shales. Geology 21(2):141–144
Zeng RS, Zhuang XG, Koukouzas N, Xu WD (2005) Characterization of trace elements in sulphur-rich late permian coals in the Heshan coal field, Guangxi, South China. Int J Coal Geol 61(1–2):87–95
Zhang PF (1990) Facies belts and depositional model of late Permian Heshan formation in Heshan, central Guangxi, southern China. Acta Sedimentol Sin 8(4):13–21
Zheng ZH (2018) Sedimentary environment and coal forming characteristics of Early Carboniferous in Guangxi. Land Resour South China 1:39–40
Zhong Z, Zhang X, Shao W (2018) Measuring global energy-related sulfur oxides emissions embodied in trade: a multi-regional and multi-sectoral analysis. Nat Hazards 95(1–2):401–418
Zhou CG, Yang Q (1999) Development on the study of sulfur in coal. Coal Geol Explor 27(1):16–20
Acknowledgments
We would like to express our gratitude to Professor Shifeng Dai for giving us sufficient suggestions to improve this manuscript. We thank the Key Laboratory of Resource Survey and Research of Hebei Province. We are also grateful to the anonymous reviewers and the journal editors.
Funding
This work is supported by the National Natural Science Foundation of China (41604069), Nature Science Foundation of Hebei Province, China (Nos. D2017402150, D2019402055), and Open Fund of Shandong Key Laboratory of Depositional Mineralization & Sedimentary Mineral, Shandong University of Science and Technology (No. DMSM2018008).
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: Shifeng Dai
Rights and permissions
About this article
Cite this article
Xu, B., Song, Y., Tian, Y. et al. Sulfur content in coal formed during different geologic periods in the Guangxi Province and the relationship with the depositional environment. Arab J Geosci 13, 294 (2020). https://doi.org/10.1007/s12517-020-5246-7
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s12517-020-5246-7