CO2浓度对煤层生物产甲烷影响机制OA
Mechanisms behind the impacts of CO2 concentration on microbial methanogenesis in coal seams
[背景]煤层中广泛存在多种原位功能微生物,一些古菌能够以CO2为底物进行产甲烷代谢,为煤层CO2生物封存与利用提供可能.然而,传统研究主要侧重煤基质降解特性,对于CO2环境下的甲烷化调节机制仍缺乏系统认识.[方法]以淮南矿区高挥发分烟煤为研究对象,通过实验室尺度下梯度浓度CO2(体积分数0%~100%)厌氧发酵产甲烷实验,结合非靶向代谢组学与微生物组学,系统探究CO2浓度对生物甲烷生成的影响机制,计算CO2消耗量与甲烷生成量以定量解析CO2与CH4之间的转化关系,构建CO2的生物化学转化路径.[结果]在CO2∶N2=4∶1氛围下(C80组)初步达到最佳阈值,在第45天获得最高产量(268.98 μmol/g煤),相较CO2∶N2=0∶5氛围下(CK组,189.27 μmol/g 煤)提升了 42.11%,CO2∶N2=9∶1(C90 组)和 CO2∶N2=1∶0(C100 组)氛围下甲烷产量则出现下降趋势.同时,C80组厌氧瓶顶空中CO2降低了 51.71%,1 mL CO2大约增加0.38 mL CH4.随CO2浓度升高至80%,微生物群落中细菌优势属的演化规律发生改变,优势菌属由副梭菌属(Paraclostridium)和肠球菌属(Enterococcus)演替为芽孢杆菌属(Bacillus)和梭菌属(Clostridium).CO2的添加明显富集了产甲烷古菌,C80组混合营养型八叠球菌属(Methanosarcina)相对丰度增加最为明显.功能基因分析数据也表明了外源CO2的介入明显增加了梭菌Wood-Ljungdahl固碳途径及产甲烷相关基因表达量.对各实验组培养前后液相差异代谢产物分析发现,高CO2浓度促进了与碳固定相关代谢物的合成(腺苷钴胺素a,c二酰胺和DAHP),加速了煤中芳烃组分的降解.结合微生物群落组成结果、PICRUSt2预测结果及非靶向代谢物分析,最终构建了细菌和古菌协同作用下煤大分子有机物降解耦合CO2-CH4转化的代谢路径.[结论]研究成果揭示了外源CO2通过三重机制强化生物甲烷生成:(1)富集了氢营养型/混合营养型产甲烷古菌;(2)提高梭菌Wood-Ljungdahl固碳途径基因丰度并促进CO2还原;(3)促进了芳香环裂解代谢与固碳辅因子合成.优化外源CO2注入浓度至80%阈值,以及通过定向富集"梭菌-八叠球菌"协同菌群以激活Wood-Ljungdahl固碳途径,这一发现为煤层气生物工程(coalbed methane bioengineering,CGB)及地质碳封存的生物转化方向提供了理论依据与新的调控策略.
[Background]Coal seams exhibit the extensive distribution of a variety of indigenous functional microorgan-isms.Among these,some archaea enable methane metabolism using CO2 as a substrate,providing the potential for the biological CO2 storage and utilization in coal seams.However,conventional studies focus primarily on the degradation characteristics of coal matrix,leading to a lack of a systematic understanding of the mechanisms governing the adjust-ment of the methanation process in CO2-bearing environments.[Methods]This study investigated the bituminous coals with a high volatile content in the Huainan mining area.Using laboratory-scale experiments on methanogenesis through anaerobic fermentation under varying CO2 concentrations(volume fraction 0%-100%),combined with untargeted meta-bolomics and microbiomics,this study systematically explored the mechanisms behind the impacts of CO2 concentra-tion on microbial methanogenesis.Furthermore,CO2 consumption and methane production were calculated for the quantitative analysis of the conversion relationship between CO2 and CH4.Accordingly,the biochemical conversion pathways of CO2 were established.[Results]The CO2 concentration threshold was preliminarily observed under an at-mosphere with a CO2∶N2 ratio of 4∶1(C80 group).In this case,a peak methane production of 268.98 μmol/g coal was identified at day 45,suggesting a 42.11%increase compared to that of the atmosphere with a CO2∶N2 ratio of 0∶5(189.27 μmol/g coal;CK group).In contrast,the methane production trended downward under atmospheres with CO2∶N2 ratios of 9∶1(C90 group)and 1∶0(C100 group).Meanwhile,the C80 group exhibited a 51.71%reduction in CO2 within the headspace of the anaerobic bottle,with 1 mL CO2 increasing about 0.38 mL CH4.As the CO2 concentra-tion increased to 80%,the evolution patterns of the dominant genera of bacteria in the microbial community changed,with the dominant genera shifting from Paraclostridium and Enterococcus to Bacillus and Clostridium.The addition of exogenous CO2 resulted in significant enrichment of methanogenic archaea,with mixotrophic Methanosarcina in the C80 group showing the most pronounced increase in relative abundance.Data from functional gene analysis also demon-strated that the intervention of exogenous CO2 significantly increased both the Wood-Ljungdahl pathway of CO2 fixa-tion in Clostridium and the expression of methanogenesis-related functional genes.The analysis of liquid-phase differen-tial metabolites before and after culture in various experimental groups shows that a high CO2 concentration promoted the synthesis of metabolites associated with carbon fixation,such as cobamamide a,c-diamide and dihydroxyacetone phosphate(DAHP),while also accelerating the degradation of aromatic components in coals.In combination with res-ults from microbial community composition,PICRUSt2 prediction,and untargeted metabolomics,this study determined the metabolic pathway that coupled the degradation of macromolecular organic matter in coals with CO2-CH4 conver-sion under the synergistic effects of bacteria and archaea.[Conclusion]The results of this study reveal that exogenous CO2 enhance microbial methanogenesis through a triple mechanism,which(1)results in the enrichment of hydrogeno-trophic/mixotrophic methanogenic archaea;(2)increases the abundance of functional genes involved in the Wood-Ljun-gdahl pathway of carbon fixation in Clostridium while also promoting CO2 reduction;and(3)facilitates both the meta-bolism induced by the cleavage of aromatic rings and the synthesis of carbon fixation cofactors.The findings that the CO2 concentration threshold is 80%and that the Wood-Ljungdahl pathway of carbon fixation can be activated by the dir-ectional enrichment of Clostridium-Sarcina synergetic microflora provide a theoretical basis and new control strategies for both coalbed methane bioengineering(CGB)and the conversion of geological to biological CO2 storage.
王俊煜;柳炳俊;蒋祥卿;陈瑞锋;薛生;周万龙;杨云都
安徽理工大学煤炭无人化开采数智技术全国重点实验室,安徽淮南 232001安徽理工大学煤炭无人化开采数智技术全国重点实验室,安徽淮南 232001||煤炭安全精准开采国家地方联合工程研究中心,安徽淮南 232001青海省能源发展(集团)有限责任公司,青海西宁 810000||安徽理工大学安全科学与工程学院,安徽淮南 232001晋能控股煤业集团轩岗煤电有限责任公司,山西忻州 034000煤炭安全精准开采国家地方联合工程研究中心,安徽淮南 232001晋能控股煤业集团轩岗煤电有限责任公司,山西忻州 034000安徽理工大学煤炭无人化开采数智技术全国重点实验室,安徽淮南 232001
能源科技
煤甲烷代谢CO2封存与利用非靶向代谢组学厌氧发酵
coalmethane metabolismCO2 storage and utilizationuntargeted metabolomicsanaerobic fermentation
《煤田地质与勘探》 2026 (4)
112-124,13
国家重点研发计划课题(2023YFC3009002)煤炭安全精准开采联合工程研究中心独立研究基金项目(EC2023006)青海能源发展(集团)有限责任公司科研项目(2024-JS-09)焦家寨煤矿研究项目(MYXGJJZKJSFW20240063)
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