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Environmental Earth Sciences

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01-04-2015 | Original Article

Minerals and potentially hazardous trace elements in marine oil shale: new insights from the Shengli River North surface mine, northern Tibet, China

Authors: Xiugen Fu, Jian Wang, Fuwen Tan, Xinglei Feng, Shengqiang Zeng, Wenbin Chen, Dong Wang

Published in: Environmental Earth Sciences | Issue 7/2015

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Abstract

The Shengli River–Changshe Mountain oil shale zone, including the Changliang Mountain–Shengli River oil shale, the Shengli River North oil shale, and the Changshe Mountain oil shale, represents potentially the largest marine oil shale resource in China. New geochemical data from the Shengli River North oil shale are presented to evaluate potentially hazardous trace elements in oil shale and to discuss possible factors controlling the geochemical anomalies. Oil shale samples from the Shengli River North area are characterized by high ash yield (59.25–66.27 %) and TOC content (4.77–9.35 %) with low total sulfur content (0.1–1.56 %) and intermediate shale oil content (3.60–16.30 %). Minerals in the Shengli River North oil shale include calcite, clay minerals, quartz, dolomite, and Fe-bearing minerals (e.g., pyrite, limonite, and hematite), and trace amounts of zeolite, apatite, and barite. Potentially hazardous trace elements in oil shale samples include As, Se, Mo, F, Ni, Cd, and Hg. Arsenic is present probably in both organic and inorganic matter. Selenium is controlled mainly by Fe-bearing (probably pyrite), while F and Cd occur mainly as apatite. The organically bound Mo and Ni are dominant, and Hg probably occurs as a substitution in the structure of pyrite, apatite and calcite. The elevated concentrations of F and Cd in the Shengli River North oil shale may be related to sediment source. Water chemistry may have played an important role for Ni and Mo enrichments, while the enrichment of Se in the oil shale samples is possibly related to hydrothermal fluids. Other elements including Hg and As are probably related to several factors.

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Amstrong-Altrin JS, Lee Y II, Verma SP, Ramasamy S (2004) Geochemistry of sandstones from the Upper Miocene Kudankulam Formation, southern India: implications for provenance, weathering and tectonic setting. J Sediment Res 74(2):285–297CrossRef

ASTM D3177-02 (2005) Annual book of ASTM standards. Test methods for total sulfur in the analysis sample of coal and coke. Gaseous fuels: coal and coke, vol. 05.06

ASTM D3174-04 (2005) Annual book of ASTM standards. Test method for ash in the analysis sample of coal and coke from coal. Gaseous fuels: coal and coke, vol. 05.06

Belyaev VK, Pedash ET, Ko NA (1989) Minor elements in coal and host rocks at the Shubarkol coal deposit. Explor Convers Miner Resources 11:12–16

Booth CA, Spears DA, Krause P, Cox AG (1999) The determination of low level trace elements in coals by laser ablation-inductively coupled plasma-mass spectrometry. Fuel 78(14):1665–1670CrossRef

Brownfield ME, Affolter RH, Cathcart JD, Johnson SY, Brownfield IK, Rice CA (2005) Geologic setting and characterization of coals and the modes of occurrence of selected elements from the Franklin coal zone, Puget group, John Henry No. 1 mine, King County, Washington, USA. Int J Coal Geol 63(3–4):247–275CrossRef

Chi QH, Yan MC (2007) Handbook of elemental abundance for applied geochemistry. Geological Publishing House, Beijing

Chou CL (1997) Geological factors affecting the abundance, distribution, and speciation of sulfur in coals. In: Yang Q (Ed) Geology of fossil fuels—coal. Proceedings of the 30th International Geological Congress, Part B, vol. 18. VSP, Utrecht

Dai SF, Ren DY, Hou XQ, Shao LY (2003) Geochemical and mineralogical anomalies of the late Permian coal in the Zhijin coalfield of southwest China and their volcanic origin. Int J Coal Geol 55(2–4):117–138CrossRef

Dai SF, Ren DY, Tang YG, Yue M, Hao LM (2005) Concentration and distribution of elements in Late Permian coals from western Guizhou Province, China. Int J Coal Geol 61(1–2):119–137CrossRef

Dai SF, Li D, Chou C-L, Zhao L, Zhang Y, Ren DY, Ma YW, Sun YY (2008a) Mineralogy and geochemistry of boehmite rich coals: new insights from the Haerwusu Surface Mine, Jungar Coalfield, Inner Mongolia, China. Int J Coal Geol 74(3–4):185–202CrossRef

Dai SF, Ren DY, Zhou YP, Chou C-L, Wang XB, Zhao L, Zhu XW (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):182–194CrossRef

Dai SF, Jiang YF, Ward CR, Gu LD, Seredin VV, Liu HD, Zhou D, Wang XB, Sun YZ, Zou JH, Ren DY (2012a) Mineralogical and geochemical compositions of the coal in the Guanbanwusu Mine, Inner Mongolia, China: further evidence for the existence of an Al (Ga and REE) ore deposit in the Jungar Coal field. Int J Coal Geol 98:10–40CrossRef

Dai SF, Ren DY, Chou C-L, Finkelman RB, Seredin VV, Zhou YP (2012b) Geochemistry of trace elements in Chinese coals: a review of abundances, genetic types, impacts on human health, and industrial utilization. Int J Coal Geol 94:3–21CrossRef

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 (2012c) 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 90–91:72–99CrossRef

Dai SF, Zhang WG, Seredin VV, Ward CR, Hower JC, Song WJ, Wang XB, Li X, Zhao LX, Kang H, Zheng LC, Wang PP, Zhou D (2013) Factors controlling geochemical and mineralogical compositions of coals preserved within marine carbonate successions: a case study from the Heshan Coalfield, southern China. Int J Coal Geol 109–110:77–100CrossRef

Dara SS (1993) A Textbook of Environmental Chemistry and Pollution Control. S. Chand, New Delhi

Dewey JF, Shackleton RM, Chang C, Sun Y (1988) The tectonic evolution of the Tibetan Plateau. Philos T R Soc A 327(1594):379–413CrossRef

Dinelli E, Tateo F (2002) Different types of fine-grained sediments associated with acid mine drainage in the Libiola Fe–Cu mine area (Ligurian Apennines, Italy). Appl Geochem 17(8):1081–1092CrossRef

Ding ZH, Zheng BS, Long JP, Belkin HE, Finkelman RB, Chen CG, Zhou DX, Zhou YS (2001) Geological and geochemical characteristics of high arsenic coals from endemic arsenosis areas in southwestern Guizhou Province, China. Appl Geochem 16(11–12):1353–1360CrossRef

Drahota P, Mihaljevič M, Grygar T, Rohovec J, Pertold Z (2011) Seasonal variations of Zn, Cu, As and Mo in arsenic-rich stream at the Mokrsko gold deposit, Czech Republic. Environ Earth Sci 62(2):429–441CrossRef

Dronen LC, Moore AE, Kozliak EI, Seams WS (2004) An assessment of acid wash and bioleaching pre-treating options to remove mercury from coal. Fuel 83(2):181–186CrossRef

DZG 20.10-1990 (1990) Geology mineral industry standard of P.R. China: rock and mineral analysis (in Chinese)

Feng XB, Hong YT (1999) Modes of occurrence of mercury in coals from Guizhou, People’s Republic of China. Fuel 78(10):1181–1188CrossRef

Feng XB, Ni JY, Hong YT, Zhu JM, Zhou B, Wang Y (1998) A preliminary study on the distribution laws of some volatile trace elements in coal of Guizhou province. Environ Chem 17:148–153 (in Chinese with English abstract)

Finkelman RB (1994) Modes of occurrence of potentially hazardous elements in coal: levels of confidence. Fuel Process Technol 39(1–3):21–34CrossRef

Finkelman RB, Palmer CA, Krasnow MR, Aruscavage PJ, Sellers GA, Dulong FT (1990) Combustion and leaching behaviour of elements in the Argonne Premium coal samples. Energy Fuel 4(6):766–767CrossRef

Fu XG, Wang J, Tan FW, Zeng YH (2009a) Sedimentological investigations of the Shengli River-Changshe Mountain oil shale (China): relationships with oil shale formation. Oil Shale 26(3):373–381CrossRef

Fu XG, Wang J, Zeng YH, Li ZX, Wang ZJ (2009b) Geochemical and palynological investigation of the Shengli River marine oil shale (China): implications for paleoenvironment and paleoclimate. Int J Coal Geol 78(3):217–224CrossRef

Fu XG, Wang J, Tan FW, Chen M, Chen WB (2010a) The Late Triassic rift-related volcanic rocks from eastern Qiangtang, northern Tibet (China): age and tectonic implications. Gondwana Res 17(1):135–144CrossRef

Fu XG, Wang J, Zeng YH, Tan FW, Feng XL (2010b) REE geochemistry of marine oil shale from the Changshe Mountain area, northern Tibet, China. Int J Coal Geol 81(3):191–199CrossRef

Fu XG, Wang J, Zeng YH, Cheng J, Tan FW (2011) Origin and mode of occurrence of trace elements in marine oil shale from the Shengli River area, northern Tibet, China. Oil Shale 28(4):487–506CrossRef

Fu XG, Wang J, Tan FW, Feng XL, Wang D, Song CY (2012) Geochemistry of terrestrial oil shale from the Lunpola area, northern Tibet, China. Int J Coal Geol 102:1–11CrossRef

Fu XG, Wang J, Zeng YH, Tan FW, Feng XL (2013) Trace elements and their behaviour during the combustion of marine oil shale from Changliang Mountain, northern Tibet, China. Enviro Earth Sci 70(3):1125–1134CrossRef

GB/T 4633-1997 (1997) National Standard of P.R. China:Determination of fluorine in coal (in Chinese)

Girardeau J, Marcoux J, Allègre CJ, Bassoullet JP, Tang YK, Xiao XC, Zao YG, Wang XB (1984) Tectonic environment and geodynamic significance of the Neo-Cimmerian Donqiao ophiolite, Bangong-Nujiang suture zone, Tibet. Nature 307:27–31CrossRef

Goodarzi F (2002) Mineralogy, elemental composition and modes of occurrence of elements in Canadian feed-coals. Fuel 81(9):1199–1213CrossRef

Greta E, Dai SF, Li X (2013) Fluorine in Bulgarian coals. Int J Coal Geol 105:16–23CrossRef

Hower JC, Robertson JD, Wong AS, Eble CF, Ruppert LF (1997) Arsenic and lead concentration in the Pond Creek and Fire Clay coal beds Eastern Kentucky coal field. Appl Geochem 12(3):281–289CrossRef

Jeng JH, Hsieh CC, Lan WH (1998) Cytotoxicity of sodium fluoride on human oral mucosal fibroblasts and its mechanisms. Cell Biol Toxicol 14(4):383–389CrossRef

Kapp P, Yin A, Manning CE, Harrison TM, Taylor MH, Ding L (2003) Tectonic evolution of the early Mesozoic blueschist-bearing Qiangtang metamorphic belt, central Tibet. Tectonics 22(4):1043

Khrustaleva GK, Andrianova TP, Medvedeva GA, Kvochkina LV, Ulanov NN (2001) Geological aspects of coal conversion to liquid fuels: a review. Geoinformmark, Moscow

Kimura T (1998) Relationships between inorganic elements and minerals in coals from the Ashibetsu district, Ishikari coal field Japan. Fuel Process Technol 56(1–2):1–19CrossRef

Kostova I, Petrov O, Kortenski J (1996) Mineralogy, geochemistry and pyrite content of Bulgarian subbituminous coals, Pernik Basin. In: Gayer R, Harris I (eds) Coalbed Methane Coal Geol, vol 109. Geological Society Publication, London

Li WX, Li XH, Li ZX (2008) Middle Neoproterozoic syn-rifting volcanic rocks in Guangfeng, South China: petrogenesis and tectonic significance. Geol Mag 145(4):475–489CrossRef

Liu Y, Liu HC, Li XH (1996) Simultaneous precise determination of 40 trace elements in rock samples using ICP-MS. Geochemica 25(6):552–558 (in Chinese with English abstract)

Liu GJ, Zheng LG, Zhang Y, Qi CC, Chen YW, Peng ZC (2007) Distribution and mode of occurrence of As, Hg and Se and Sulfur in coal Seam 3 of the Shanxi Formation, Yanzhou Coalfield, China. Int J Coal Geol 71(2–3):371–385CrossRef

Liu ZJ, Yang HL, Dong QS, Zhu JW, Guo W, Ye SQ, Liu R, Meng QT, Zhang HL, Gan SC (2009) Oil shale in China. Petroleum Industry Press (in Chinese with English abstract)

Lu BH (1996) Occurrence mode of fluorine and chlorine in coal seam of China. Geol Explor 24(1):9–11 (in Chinese, with English Abstract)

Luo KL, Ren DY, Xu LR, Dai SF, Cao DY, Feng FJ, Tan JA (2004) Fluorine content and distribution pattern in Chinese coals. Int J Coal Geol 57(2):143–149CrossRef

Lyons PC, Palmer CA, Bostick NH, Fletcher JD, Dulong FT, Brown FW, Brown ZA, Krasnow MR, Romankiw LA (1989) Chemistry and origin of minor and trace elements in vitrinite concentrates from a rank series from the Eastern United States, England and Australia. Int J Coal Geol 13(1–4):481–527CrossRef

Nie S, Yin A, Rowley DB, Jin Y (1994) Exhumation of the Dabie Shan ultra-high pressure rocks and accumulation of the Songpan-Ganzi flysch sequence, central China. Geology 22(11):999–1002CrossRef

Notcutt G, Davies F (2001) Environmental accumulation of airborne fluorides in Romania. Environ Geochem Health 23(1):43–51CrossRef

Nriagu JQ, Pacyna JM (1988) Quantitative assessment of worldwide contamination of the air, water and soils with trace metals. Nature 333:134–139CrossRef

Pearce JA, Mei H (1988) Volcanic rocks of the 1985 Tibet Geotraverse: Lhasa to Golmud. Philos T R Soc A 327(1594):169–201CrossRef

Qian J, Wang SL (2003) Oil shale development in China. Oil shale 20:356–359

Rietveld HM (1969) A profile refinement method for nuclear and magnetic structures. J Appl Cryst 2:65–71CrossRef

Riley KW, French DH, Farrell OP, Wood RA, Huggins FE (2012) Modes of occurrence of trace and minor elements in some Australian coals. Int J Coal Geol 94:214–224CrossRef

Ruan CD, Ward CR (2002) Quantitative X-Ray powder diffraction analysis of clay minerals in Australian coals using Rietveld methods. Appl Clay Sci 21(5–6):227–240CrossRef

Ruppert LF, Hower JC, Eble CF (2005) Arsenic-bearing pyrite and marcasite in the fire clay coal bed, Middle Pennsylvanian Breathitt Formation, eastern Kentucky. Int J Coal Geol 63(1–2):27–35CrossRef

Sia SG, Abdullah WH (2012) Enrichment of arsenic, lead, and antimony in Balingian coal from Sarawak, Malaysia: modes of occurrence, origin, and partitioning behaviour during coal combustion. Int J Coal Geol 101:1–15CrossRef

Song DY, Qin Y, Zhang JY, Wang WF, Zheng CG (2007) Concentration and distribution of trace elements in some coals from Northern China. Int J Coal Geol 69(3):179–191CrossRef

Song DY, Ma YJ, Qin Y, Wang WF, Zheng CG (2011) Volatility and mobility of some trace elements in coal from Shizuishan Power Plant. J Fuel Chem Technol 39(5):328–332CrossRef

Spears DA, Zheng Y (1999) Geochemistry and origin of elements in some UK coals. Int J Coal Geol 38(3–4):161–179CrossRef

Sun J, Jervis RE (1986) Distribution characterization of trace elements during coal combustion. China Sci Bull (A) 16:1285–1294

Swaine DJ (1990) Trace Elements in Coal. Butterworths, London

Swaine DJ (2000) Why trace elements are important. Fuel Process Technol 65–66:21–23CrossRef

Tang Y, Wang F (1984) Primary analysis of the tectonic environment of the ophiolite in Northern Xizang. Himalayan Geol 2:99–113

Taylor SR, McLennan SM (1995) The geochemical evolution of the continental crust. Rev Geophys 33(2):241–265CrossRef

Troshin YP, Lomonosov IS, Lomonosova TK (2001) Geochemistry of the ore-bearing elements in sediments of the Cenozoic depressions, Baikal rift zone. Geol Geophys 42:348–361

Wagner NJ, Hlatshwayo B (2005) The occurrence of potentially hazardous trace elements in five Highveld coals, South Africa. Int J Coal Geol 63(3–4):228–246CrossRef

Wang L, Reddy KJ, Munn LC (1994) Geochemical modeling for predicting potential solid phases controlling the dissolved molybdenum in coal overburden, Powder River Basin, WY, U.S.A. Appl Geochem 9(1):37–43CrossRef

Wang PJ, Wang DP, Chang P, Li H (1996) Metallic biomineralization of continental black shales. J Changchun University of Earth Sci 26(1):47–53 (in Chinese with English abstract)

Wang J, Fu XG, Chen WX, Wang ZJ, Tan FW, Chen M, Zhuo JW (2008) Chronology and geochemistry of the volcanic rocks in Woruo mountain region, northern Qiangtang depression: implications to the Late Triassic volcanic-sedimentary events. Sci China Earth Sc 51(2):194–205CrossRef

Wang XB, Dai SF, Sun YY, Li D, Zhang WG, Zhang Y, Luo YB (2011) Modes of occurrence of fluorine in the Late Paleozoic No. 6 coal from the Haerwusu Surface Mine, Inner Mongolia, China. Fuel 90(1):248–254CrossRef

Ward CR, Spears DA, Booth CA, Staton I, Gurba LW (1999) Mineral matter and trace elements in coals of the Gunnedah Basin, New South Wales, Australia. Int J Coal Geol 40(4):281–308CrossRef

Yang J (2006) Concentrations and modes of occurrence of trace elements in the Late Permian coals from the Puan Coalfield, southwestern Guizhou, China. Environ Geochem Heal 28(6):567–576CrossRef

Yeomans J, Bremmer JM (1989) A rapid and precise method four routine determination of organic carbon in soil. Commun Soil Sci Plan 19:1467–1476CrossRef

Yin A, Harrison TM (2000) Geologic evolution of the Himalayan-Tibetan Orogen. Annu Rev Earth Planet Sci 28:211–280CrossRef

Yudovich YE, Ketris MP (2006) Selenium in coal: a review. Int J Coal Geol 67(1–2):112–126CrossRef

Zhao FH, Ren DY, Peng SP, Wang YQ, Zhang JY, Ding ZH, Cong ZY (2003) The modes of occurrence of arsenic in coal. Adv Earth Sci 18:214–220 (in Chinese with English abstract)

Zhou JB, Zhuang XG, Alastuey A, Querol X, Li JH (2010) Geochemistry and mineralogy of coal in the recently explored Zhundong large coal field in the Junggar basin, Xinjiang province, China. Int J Coal Geol 82(1–2):51–67CrossRef

Zhu JM, Zheng BS (2004) Distribution of selenium in a mini-landscape of Yutangba, Enshi, Hubei Province, China. Appl Geochem 16(11–12):1333–1344

Zhu JM, Zuo W, Liang XB, Li SH, Zheng BS (2004) Occurrence of native selenium in Yutangba and its environmental implications. Appl Geochem 19(3):461–467CrossRef

Zhuang XG, Querol X, Plana F, Alastuey A, Lopez-Soler A, Wang H (2003) Determination of elemental affinities by density fractionation of bulk coal samples from the Chongqing coal district, Southwestern China. Int J Coal Geol 55(2–4):103–115CrossRef

Zhuang XG, Querol X, Alastuey A, Plana F, Moreno N, Andrés JM, Wang JL (2007) Mineralogy and geochemistry of the coals from the Chongqing and Southeast Hubei coal mining districts, South China. Int J Coal Geol 71(2–3):263–275CrossRef

Title: Minerals and potentially hazardous trace elements in marine oil shale: new insights from the Shengli River North surface mine, northern Tibet, China
Authors: Xiugen Fu
Jian Wang
Fuwen Tan
Xinglei Feng
Shengqiang Zeng
Wenbin Chen
Dong Wang
Publication date: 01-04-2015
Publisher: Springer Berlin Heidelberg
Published in: Environmental Earth Sciences / Issue 7/2015
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-014-3609-7

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