Contribution of abiotic methane polymerization of C2+ hydrocarbons in highly mature natural gas reservoirs

IF 2.6 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Organic Geochemistry Pub Date : 2024-05-15 DOI:10.1016/j.orggeochem.2024.104798
Yun Li , Wenmin Jiang , Wen Liu , Yongqiang Xiong , Ping'an Peng
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Abstract

The formation and evolution of thermogenic gases were investigated using a combination of intermolecular and intramolecular isotope analyses of 32 natural gas samples collected from the Sichuan and Tarim basins (China) and the Arkoma Basin (USA). Three evolution stages (I–III) were identified: In stage I, hydrocarbon gases are produced through thermal decomposition of organic matter, and kinetic isotope effects in C–C bond breakage control their isotopic distributions; In stage II, C2–C5 hydrocarbons crack with increasing thermal maturity, with their formation and decomposition tending toward thermodynamic equilibrium, and at the end of this stage, the intermolecular and intramolecular isotopic compositions of gaseous hydrocarbons are in thermodynamic equilibrium; A remarkable feature of stage III is the surface-catalyzed abiotic polymerization of methane, which provides a critical origin of C2+ hydrocarbons in this stages and leads to isotopic anomalies in C2+ hydrocarbons, including the reversal of δ13C distributions of C1–C3 and the reverse evolution trend of SP value of propane (i.e., tending to be positive). The contribution of C2+ hydrocarbons from the abiotic polymerization of methane can be determined based on a two-end member model. C2+ hydrocarbons in the Changning shale gases are all generated from abiotic methane polymerization, and the contribution ratio in the Weiyuan shale gases is about 85 %, while, the contribution of C2+ hydrocarbons in dry gases from the Tarim Basin formed by this way is no more than 55 %. High methane abundance, high temperature, and abundant catalyst are beneficial to abiotic methane polymerization.

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高度成熟天然气储层中 C2+ 碳氢化合物非生物甲烷聚合的贡献
通过对采集自四川盆地、塔里木盆地(中国)和阿科玛盆地(美国)的 32 个天然气样本进行分子间和分子内同位素分析,研究了热成气体的形成和演化过程。确定了三个演化阶段(I-III):在第一阶段,烃类气体是通过有机物的热分解产生的,C-C 键断裂的动力学同位素效应控制着它们的同位素分布;在第二阶段,C2-C5 碳氢化合物随着热成熟度的增加而裂解,其形成和分解趋于热力学平衡,在这一阶段结束时,气态碳氢化合物的分子间和分子内同位素组成处于热力学平衡状态;第 III 阶段的一个显著特点是甲烷的表面催化非生物聚合,这为该阶段 C2+ 碳氢化合物的产生提供了一个关键源头,并导致 C2+ 碳氢化合物的同位素异常,包括 C1-C3 的 δ13C 分布逆转和丙烷 SP 值的逆向演化趋势(即 C1-C3 的 δ13C 分布逆转和丙烷 SP 值的逆向演化趋势(即 C1-C3 的 δ13C 分布逆转和丙烷 SP 值的逆向演化趋势))。e.,趋于正值)。甲烷非生物聚合产生的 C2+ 碳氢化合物的贡献可根据两端成员模型确定。长宁页岩气中的 C2+ 碳氢化合物全部由非生物甲烷聚合生成,在威远页岩气中的贡献率约为 85%,而在塔里木盆地通过这种方式形成的干燥气体中,C2+ 碳氢化合物的贡献率不超过 55%。高甲烷丰度、高温和丰富的催化剂有利于非生物甲烷聚合。
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来源期刊
Organic Geochemistry
Organic Geochemistry 地学-地球化学与地球物理
CiteScore
5.50
自引率
6.70%
发文量
100
审稿时长
61 days
期刊介绍: Organic Geochemistry serves as the only dedicated medium for the publication of peer-reviewed research on all phases of geochemistry in which organic compounds play a major role. The Editors welcome contributions covering a wide spectrum of subjects in the geosciences broadly based on organic chemistry (including molecular and isotopic geochemistry), and involving geology, biogeochemistry, environmental geochemistry, chemical oceanography and hydrology. The scope of the journal includes research involving petroleum (including natural gas), coal, organic matter in the aqueous environment and recent sediments, organic-rich rocks and soils and the role of organics in the geochemical cycling of the elements. Sedimentological, paleontological and organic petrographic studies will also be considered for publication, provided that they are geochemically oriented. Papers cover the full range of research activities in organic geochemistry, and include comprehensive review articles, technical communications, discussion/reply correspondence and short technical notes. Peer-reviews organised through three Chief Editors and a staff of Associate Editors, are conducted by well known, respected scientists from academia, government and industry. The journal also publishes reviews of books, announcements of important conferences and meetings and other matters of direct interest to the organic geochemical community.
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