古近纪超高有机硫煤的古环境解码

IF 5.6 2区 工程技术 Q2 ENERGY & FUELS International Journal of Coal Geology Pub Date : 2024-07-08 DOI:10.1016/j.coal.2024.104559
Tushar Adsul , Molly D. O'Beirne , David A. Fike , Santanu Ghosh , Josef P. Werne , William P. Gilhooly III , Paul C. Hackley , Javin J. Hatcherian , Bright Philip , Bodhisatwa Hazra , Sudip Bhattacharyya , Ritam Konar , Atul Kumar Varma
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This investigation decodes the paleomire conditions of the Paleogene SHOS coals from Meghalaya, India, using sulfur isotopic compositions (<em>δ</em><sup>34</sup>S) of organic sulfur (<em>δ</em><sup>34</sup>S<sub>OS</sub>) and pyritic sulfur (<em>δ</em><sup>34</sup>S<sub>Py</sub>) along with organic petrography, pyrite morphology and trace element ratios. Thirty coal samples were collected from the Jaintia Hills in the east, Khasi Hills in the middle, and Garo Hills in the west of Meghalaya. The organic sulfur content in the Garo, Khasi, and Jaintia coals varies from 1.0 to 3.3 wt%, 1.4 to 13.8 wt%, and 1.0 to 7.2 wt%, respectively. Further, after separation from pyritic sulfur and sulfate sulfur phases, the organic sulfur content ranges from 54.4 to 69.2%, 63.8 to 79.9%, and 59.3 to 73.8%, in the Garo, Khasi, and Jaintia Hills, respectively, suggesting the SHOS nature of these coal samples. The <em>δ</em><sup>34</sup>S<sub>Py</sub> varies from −29.3 ‰ to +5.7 ‰, −21.3 ‰ to +27.3 ‰, and  −12.1 ‰ to −4.3 ‰, in the Jaintia, Khasi, and Garo Hills, respectively, while the <em>δ</em><sup>34</sup>S<sub>OS</sub> fluctuates from −4.6 ‰ to +3.7 ‰, −9.3 ‰ to +7.8 ‰, and − 9.0 ‰ to −5.0 ‰, respectively. The <em>δ</em><sup>34</sup>S values of pyrite and organic sulfur (OS) in Jaintia coals are <sup>34</sup>S depleted compared to seawater sulfate (+22 ‰), leading to fractionations in the range of −51.3 ‰ to −16.3 ‰ (mean − 31.6 ‰) and − 26.6 ‰ to −18.3 ‰ (mean − 23.1 ‰) for pyritic and organic sulfur (OS), respectively. Pyrite in Khasi coals show a relatively heavier <em>δ</em><sup>34</sup>S composition averaging at −20.5 ‰, whereas organic sulfur (OS) isotope compositions range from −31.3 ‰ to −14.2 ‰ with a mean of −22.6 ‰. Pyrite and OS in the Garo coals are depleted compared to seawater sulfate. Isotope variations in the Jaintia, Khasi, and Garo coals indicate microbial sulfate reduction (MSR) of seawater sulfate. Large isotopic fractionations between Eocene seawater sulfate and pyritic sulfur (<em>Δ</em><sup>34</sup>S<sub>SO4Eocene – pyrite</sub> = up to −51.3 ‰; mean − 31.6 ‰) in Jaintia coals indicate their possible formation in the water column/near the sediment-seawater interface (open system) and also hint toward dissimilatory sulfate reduction pathways that prevailed under anoxic redox conditions. However, mean values of <em>Δ</em><sup>34</sup>S<sub>SO4Eocene – pyrite</sub> (−20.5 ‰) in the Khasi coals imply pyrite formation deeper in the sediments (more closed system) under dysoxic conditions. The dominance of OS over pyritic sulfur, framboidal pyrite, and its microcrystal size distributions in Jaintia coals may suggest syngenetic pyrite formation in open water reducing/anoxic conditions under paralic environments. Elevated Sr/Ba and U/Th values in these coals further confirm the anoxic conditions. Nevertheless, the presence of euhedral pyrite with the alleviated pyrite framboids in the Khasi coals and their complete absence in the Garo coals may suggest dysoxic-suboxic and suboxic-oxic depositional conditions, respectively. The isotopic signatures of the Garo coals suggest sulfur contribution from the parent paleobiota and MSR under a freshwater-oxic environment. Insignificant fractionations between <em>δ</em><sup>34</sup>S<sub>Py</sub> and <em>δ</em><sup>34</sup>S<sub>OS</sub> indicate limited iron and sulfate availability for additional sulfur cycling and disproportionation reactions, typical of oxic conditions. The absence of framboidal pyrite, elevated sulfate concentration, and mean Sr/Ba and U/Th values of 0.5 and 0.3, respectively, further suggest the freshwater peat deposition in the Garo Hills under limnotelmatic to telmatic freshwater conditions. Moreover, high inertinite content (I<sub>mmf</sub> = 9.77–33.16 vol%), possibly induced by atmospheric peat exposure, supports the interpretation of suboxic-oxic paleomire conditions in Garo Hills. Gradually decreasing mineral matter content from Jaintia (mean 13.6 vol%) to Garo coals (mean 7.4 vol%) additionally projects a transition from mesotrophic brackish to freshwater limnotelmatic environment, complementing the shift in the paleomire condition from eastern (Jaintia) to western (Garo) Meghalayan Hills.</p></div>","PeriodicalId":13864,"journal":{"name":"International Journal of Coal Geology","volume":null,"pages":null},"PeriodicalIF":5.6000,"publicationDate":"2024-07-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Decoding paleomire conditions of paleogene superhigh-organic-sulfur coals\",\"authors\":\"Tushar Adsul ,&nbsp;Molly D. O'Beirne ,&nbsp;David A. 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This investigation decodes the paleomire conditions of the Paleogene SHOS coals from Meghalaya, India, using sulfur isotopic compositions (<em>δ</em><sup>34</sup>S) of organic sulfur (<em>δ</em><sup>34</sup>S<sub>OS</sub>) and pyritic sulfur (<em>δ</em><sup>34</sup>S<sub>Py</sub>) along with organic petrography, pyrite morphology and trace element ratios. Thirty coal samples were collected from the Jaintia Hills in the east, Khasi Hills in the middle, and Garo Hills in the west of Meghalaya. The organic sulfur content in the Garo, Khasi, and Jaintia coals varies from 1.0 to 3.3 wt%, 1.4 to 13.8 wt%, and 1.0 to 7.2 wt%, respectively. Further, after separation from pyritic sulfur and sulfate sulfur phases, the organic sulfur content ranges from 54.4 to 69.2%, 63.8 to 79.9%, and 59.3 to 73.8%, in the Garo, Khasi, and Jaintia Hills, respectively, suggesting the SHOS nature of these coal samples. The <em>δ</em><sup>34</sup>S<sub>Py</sub> varies from −29.3 ‰ to +5.7 ‰, −21.3 ‰ to +27.3 ‰, and  −12.1 ‰ to −4.3 ‰, in the Jaintia, Khasi, and Garo Hills, respectively, while the <em>δ</em><sup>34</sup>S<sub>OS</sub> fluctuates from −4.6 ‰ to +3.7 ‰, −9.3 ‰ to +7.8 ‰, and − 9.0 ‰ to −5.0 ‰, respectively. The <em>δ</em><sup>34</sup>S values of pyrite and organic sulfur (OS) in Jaintia coals are <sup>34</sup>S depleted compared to seawater sulfate (+22 ‰), leading to fractionations in the range of −51.3 ‰ to −16.3 ‰ (mean − 31.6 ‰) and − 26.6 ‰ to −18.3 ‰ (mean − 23.1 ‰) for pyritic and organic sulfur (OS), respectively. Pyrite in Khasi coals show a relatively heavier <em>δ</em><sup>34</sup>S composition averaging at −20.5 ‰, whereas organic sulfur (OS) isotope compositions range from −31.3 ‰ to −14.2 ‰ with a mean of −22.6 ‰. Pyrite and OS in the Garo coals are depleted compared to seawater sulfate. Isotope variations in the Jaintia, Khasi, and Garo coals indicate microbial sulfate reduction (MSR) of seawater sulfate. Large isotopic fractionations between Eocene seawater sulfate and pyritic sulfur (<em>Δ</em><sup>34</sup>S<sub>SO4Eocene – pyrite</sub> = up to −51.3 ‰; mean − 31.6 ‰) in Jaintia coals indicate their possible formation in the water column/near the sediment-seawater interface (open system) and also hint toward dissimilatory sulfate reduction pathways that prevailed under anoxic redox conditions. However, mean values of <em>Δ</em><sup>34</sup>S<sub>SO4Eocene – pyrite</sub> (−20.5 ‰) in the Khasi coals imply pyrite formation deeper in the sediments (more closed system) under dysoxic conditions. The dominance of OS over pyritic sulfur, framboidal pyrite, and its microcrystal size distributions in Jaintia coals may suggest syngenetic pyrite formation in open water reducing/anoxic conditions under paralic environments. Elevated Sr/Ba and U/Th values in these coals further confirm the anoxic conditions. Nevertheless, the presence of euhedral pyrite with the alleviated pyrite framboids in the Khasi coals and their complete absence in the Garo coals may suggest dysoxic-suboxic and suboxic-oxic depositional conditions, respectively. The isotopic signatures of the Garo coals suggest sulfur contribution from the parent paleobiota and MSR under a freshwater-oxic environment. Insignificant fractionations between <em>δ</em><sup>34</sup>S<sub>Py</sub> and <em>δ</em><sup>34</sup>S<sub>OS</sub> indicate limited iron and sulfate availability for additional sulfur cycling and disproportionation reactions, typical of oxic conditions. The absence of framboidal pyrite, elevated sulfate concentration, and mean Sr/Ba and U/Th values of 0.5 and 0.3, respectively, further suggest the freshwater peat deposition in the Garo Hills under limnotelmatic to telmatic freshwater conditions. 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引用次数: 0

摘要

超高有机硫(SHOS)煤(有机硫含量>4 wt%)是世界上少数几个著名地点发现的独特煤炭矿床。要形成SHOS煤,必须满足特定的泥炭堆积和保存条件。有机硫是这类煤炭的主要成分,根据当时的古地层条件,它可能有不同的来源。了解这些古环境条件有助于了解 SHOS 煤的形成机制。这项研究利用有机硫(δ34SOS)和黄铁矿硫(δ34Spy)的硫同位素组成(δ34S)以及有机岩相学、黄铁矿形态学和微量元素比率,解译了印度梅加拉亚古近纪 SHOS 煤的古环境条件。从梅加拉亚邦东部的耆提亚山、中部的卡西山和西部的加罗山采集了 30 个煤炭样本。Garo、Khasi 和 Jaintia 煤炭中的有机硫含量分别为 1.0 至 3.3 wt%、1.4 至 13.8 wt% 和 1.0 至 7.2 wt%。此外,从黄铁矿硫相和硫酸盐硫相中分离后,加罗山、卡西山和詹蒂亚山的有机硫含量分别为 54.4% 至 69.2%、63.8% 至 79.9% 和 59.3% 至 73.8%,表明这些煤样具有 SHOS 性质。δ34SPy在金迪亚山、卡西山和加罗山的变化范围分别为-29.3‰至+5.7‰、-21.3‰至+27.3‰和-12.1‰至-4.3‰,而δ34SOS的波动范围分别为-4.6‰至+3.7‰、-9.3‰至+7.8‰和-9.0‰至-5.0‰。与海水硫酸盐(+22 ‰)相比,詹蒂亚煤炭中黄铁矿和有机硫(OS)的δ34S值为贫化34S,导致黄铁矿和有机硫(OS)的分馏范围分别为-51.3‰至-16.3‰(平均值-31.6‰)和-26.6‰至-18.3‰(平均值-23.1‰)。卡西煤中黄铁矿的δ34S组成相对较重,平均值为-20.5‰,而有机硫(OS)同位素组成的范围为-31.3‰至-14.2‰,平均值为-22.6‰。与海水硫酸盐相比,加罗煤中的黄铁矿和氧化硫含量较低。Jaintia、Khasi和Garo煤炭中的同位素变化表明海水硫酸盐的微生物硫酸盐还原作用(MSR)。Jaintia 煤炭中始新世海水硫酸盐与黄铁矿硫(Δ34SSO4Eocene - 黄铁矿 = 高达 -51.3‰;平均值 - 31.6‰)之间的同位素分馏较大,表明它们可能形成于水体/沉积物-海水界面附近(开放系统),也暗示了缺氧氧化还原条件下普遍存在的硫酸盐异嗜还原途径。然而,卡西煤中 Δ34SSO4Eocene - 黄铁矿的平均值(-20.5 ‰)意味着在缺氧条件下黄铁矿形成于沉积物的更深处(更封闭的系统)。在贾恩蒂亚煤炭中,OS 比黄铁矿硫、框架黄铁矿占优势,其微晶尺寸分布可能表明黄铁矿是在准缺氧环境下的开放水体还原/缺氧条件下形成的。这些煤炭中升高的 Sr/Ba 值和 U/Th 值进一步证实了缺氧条件。尽管如此,卡西煤中存在的八面体黄铁矿与减轻的黄铁矿框架结构,以及加罗煤中完全不存在的黄铁矿框架结构,可能分别表明了缺氧-亚缺氧和亚缺氧-缺氧沉积条件。加罗煤炭的同位素特征表明,在淡水-缺氧环境下,母体古生物群和 MSR 对硫有贡献。δ34SPy和δ34SOS之间的分馏不明显,表明铁和硫酸盐的可用性有限,无法进行额外的硫循环和歧化反应,这是典型的缺氧条件。镜铁矿的缺失、硫酸盐浓度的升高以及 Sr/Ba 和 U/Th 的平均值分别为 0.5 和 0.3,进一步表明加罗山的淡水泥炭沉积是在石灰岩型到透镜型淡水条件下进行的。此外,惰性气体含量较高(Immf = 9.77-33.16 vol%),可能是由于泥炭暴露在大气中造成的,这支持了对加罗山亚缺氧-缺氧古环境条件的解释。矿物物质含量从 Jaintia 煤(平均 13.6 vol%)逐渐减少到 Garo 煤(平均 7.4 vol%),这进一步推测了中营养咸水环境向淡水石灰岩环境的过渡,补充了古地层条件从东部(Jaintia)到西部(Garo)梅加拉亚山脉的转变。
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Decoding paleomire conditions of paleogene superhigh-organic-sulfur coals

Superhigh-organic‑sulfur (SHOS) coals (coals with organic sulfur content >4 wt%) are unique coal deposits found at a few notable locations in the world. Specific peat accumulation and preservation conditions must be met to form SHOS coals. Organic sulfur is a major constituent of such coals, and it may have various sources depending on the prevailing paleomire conditions. Understanding such paleomire conditions sheds light on the formation mechanisms of SHOS coals. This investigation decodes the paleomire conditions of the Paleogene SHOS coals from Meghalaya, India, using sulfur isotopic compositions (δ34S) of organic sulfur (δ34SOS) and pyritic sulfur (δ34SPy) along with organic petrography, pyrite morphology and trace element ratios. Thirty coal samples were collected from the Jaintia Hills in the east, Khasi Hills in the middle, and Garo Hills in the west of Meghalaya. The organic sulfur content in the Garo, Khasi, and Jaintia coals varies from 1.0 to 3.3 wt%, 1.4 to 13.8 wt%, and 1.0 to 7.2 wt%, respectively. Further, after separation from pyritic sulfur and sulfate sulfur phases, the organic sulfur content ranges from 54.4 to 69.2%, 63.8 to 79.9%, and 59.3 to 73.8%, in the Garo, Khasi, and Jaintia Hills, respectively, suggesting the SHOS nature of these coal samples. The δ34SPy varies from −29.3 ‰ to +5.7 ‰, −21.3 ‰ to +27.3 ‰, and  −12.1 ‰ to −4.3 ‰, in the Jaintia, Khasi, and Garo Hills, respectively, while the δ34SOS fluctuates from −4.6 ‰ to +3.7 ‰, −9.3 ‰ to +7.8 ‰, and − 9.0 ‰ to −5.0 ‰, respectively. The δ34S values of pyrite and organic sulfur (OS) in Jaintia coals are 34S depleted compared to seawater sulfate (+22 ‰), leading to fractionations in the range of −51.3 ‰ to −16.3 ‰ (mean − 31.6 ‰) and − 26.6 ‰ to −18.3 ‰ (mean − 23.1 ‰) for pyritic and organic sulfur (OS), respectively. Pyrite in Khasi coals show a relatively heavier δ34S composition averaging at −20.5 ‰, whereas organic sulfur (OS) isotope compositions range from −31.3 ‰ to −14.2 ‰ with a mean of −22.6 ‰. Pyrite and OS in the Garo coals are depleted compared to seawater sulfate. Isotope variations in the Jaintia, Khasi, and Garo coals indicate microbial sulfate reduction (MSR) of seawater sulfate. Large isotopic fractionations between Eocene seawater sulfate and pyritic sulfur (Δ34SSO4Eocene – pyrite = up to −51.3 ‰; mean − 31.6 ‰) in Jaintia coals indicate their possible formation in the water column/near the sediment-seawater interface (open system) and also hint toward dissimilatory sulfate reduction pathways that prevailed under anoxic redox conditions. However, mean values of Δ34SSO4Eocene – pyrite (−20.5 ‰) in the Khasi coals imply pyrite formation deeper in the sediments (more closed system) under dysoxic conditions. The dominance of OS over pyritic sulfur, framboidal pyrite, and its microcrystal size distributions in Jaintia coals may suggest syngenetic pyrite formation in open water reducing/anoxic conditions under paralic environments. Elevated Sr/Ba and U/Th values in these coals further confirm the anoxic conditions. Nevertheless, the presence of euhedral pyrite with the alleviated pyrite framboids in the Khasi coals and their complete absence in the Garo coals may suggest dysoxic-suboxic and suboxic-oxic depositional conditions, respectively. The isotopic signatures of the Garo coals suggest sulfur contribution from the parent paleobiota and MSR under a freshwater-oxic environment. Insignificant fractionations between δ34SPy and δ34SOS indicate limited iron and sulfate availability for additional sulfur cycling and disproportionation reactions, typical of oxic conditions. The absence of framboidal pyrite, elevated sulfate concentration, and mean Sr/Ba and U/Th values of 0.5 and 0.3, respectively, further suggest the freshwater peat deposition in the Garo Hills under limnotelmatic to telmatic freshwater conditions. Moreover, high inertinite content (Immf = 9.77–33.16 vol%), possibly induced by atmospheric peat exposure, supports the interpretation of suboxic-oxic paleomire conditions in Garo Hills. Gradually decreasing mineral matter content from Jaintia (mean 13.6 vol%) to Garo coals (mean 7.4 vol%) additionally projects a transition from mesotrophic brackish to freshwater limnotelmatic environment, complementing the shift in the paleomire condition from eastern (Jaintia) to western (Garo) Meghalayan Hills.

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来源期刊
International Journal of Coal Geology
International Journal of Coal Geology 工程技术-地球科学综合
CiteScore
11.00
自引率
14.30%
发文量
145
审稿时长
38 days
期刊介绍: The International Journal of Coal Geology deals with fundamental and applied aspects of the geology and petrology of coal, oil/gas source rocks and shale gas resources. The journal aims to advance the exploration, exploitation and utilization of these resources, and to stimulate environmental awareness as well as advancement of engineering for effective resource management.
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