Enhancement of Biomethane Generation from Coal by Anaerobically Co-Degrading with Biological and Chemical Products of Straw Treatment

IF 1 4区 生物学 Q4 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Applied Biochemistry and Microbiology Pub Date : 2023-10-02 DOI:10.1134/S0003683823050101
Y. Liu, Y. Cheng, Y. Li, H. Guo, Z. Huang, M. Urynowicz
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Abstract

Co-degradation of coal and straw is an effective way to enhance the generation of biogenic coalbed methane (CBM). However, solid straw is not easily injected into coal seam and the complex and rigid structure of straw also makes the direct degradation inefficient. Therefore, straw was biologically and chemically treated, here, to obtain a liquid product which was further co-degraded with coal to produce methane. The results showed that the methane productions in co-degradations of coal and liquid products were all higher than that from coal. The highest methane production was observed in co-degradation of coal and biological liquid products with fresh microflora (MRC1) which was about 600 μmol and even higher than that in co-degradation of coal and straw. Organic acids were dominant in all liquid products whose contents ranged from 25.4 to 73.1%, and were positively related with methane productions in co-degradation. After co-degradation, the microbial community in MRC1 was closer to the original microflora, and the coal sample was degraded deeper than after cultivation with only coal as revealed by FTIR results. These results suggested that the liquefaction of straw by pretreatment can perfectly solve the injection and degradation limitation in co-degradation, and organic acids would be the essential factors in the interaction between coal and straw. Based on that, a new method was proposed to enhance biogenic CBM generation in coal seam or goaf by injecting microorganisms and liquid products or organic acids associated with rice straw.

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秸秆处理生化产物厌氧共降解提高煤中生物甲烷的生成
煤与秸秆的共降解是促进生物煤层气生成的有效途径。然而,固体秸秆不易注入煤层,秸秆结构复杂坚硬,直接降解效率低。因此,在这里,对秸秆进行生物和化学处理,以获得液体产品,该产品与煤进一步共降解,产生甲烷。结果表明,煤和液体产物共降解的甲烷产量均高于煤。在煤和生物液体产物与新鲜菌群(MRC1)的共降解中观察到最高的甲烷产量,约为600μmol,甚至高于煤和秸秆的共降解。有机酸在所有液体产物中占主导地位,其含量在25.4%至73.1%之间,并且在共降解中与甲烷的产生呈正相关。FTIR结果显示,共降解后,MRC1中的微生物群落更接近原始微生物群落,并且煤样品比仅用煤培养后降解更深。这些结果表明,秸秆预处理液化可以很好地解决共降解中的注入和降解限制,有机酸将是煤与秸秆相互作用的重要因素。在此基础上,提出了一种通过注入微生物和与稻草相关的液体产物或有机酸来提高煤层或采空区生物煤层气生成的新方法。
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来源期刊
Applied Biochemistry and Microbiology
Applied Biochemistry and Microbiology 生物-生物工程与应用微生物
CiteScore
1.70
自引率
12.50%
发文量
75
审稿时长
6-12 weeks
期刊介绍: Applied Biochemistry and Microbiology is an international peer reviewed journal that publishes original articles on biochemistry and microbiology that have or may have practical applications. The studies include: enzymes and mechanisms of enzymatic reactions, biosynthesis of low and high molecular physiologically active compounds; the studies of their structure and properties; biogenesis and pathways of their regulation; metabolism of producers of biologically active compounds, biocatalysis in organic synthesis, applied genetics of microorganisms, applied enzymology; protein and metabolic engineering, biochemical bases of phytoimmunity, applied aspects of biochemical and immunochemical analysis; biodegradation of xenobiotics; biosensors; biomedical research (without clinical studies). Along with experimental works, the journal publishes descriptions of novel research techniques and reviews on selected topics.
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