氨抑制不同有机负荷率下基于粪便的连续生物甲烷化过程及相关微生物群落动态。

Ammonia-induced inhibition of manure-based continuous biomethanation process under different organic loading rates and associated microbial community dynamics.

机构信息

Department of Hydraulics, Soil Science and Agricultural Engineering, School of Agriculture, Aristotle University of Thessaloniki, GR-54124 Thessaloniki, Greece.

Department of Biochemistry and Biotechnology, University of Thessaly, GR-41500 Larissa, Greece.

出版信息

Bioresour Technol. 2021 Jan;320(Pt A):124323. doi: 10.1016/j.biortech.2020.124323. Epub 2020 Oct 28.

DOI:10.1016/j.biortech.2020.124323

PMID:33157441

Abstract

Three Continuously Stirred Tank Reactors (CTSRs) were operating at steady state conditions with Organic Loading Rates (OLR) of 2.09, 3.024 and 4.0 g VS L d. Glucose was used as the sole factor for increasing the OLR, linking the increase of the OLR with the C/N ratio increase. The reactors were stressed by increasing the ammonia concentration to 5 g L from 1.862 g L. The results showed elevating inhibition of the anaerobic process by increasing the C/N ratio just by increasing the OLR, under the high ammonia concentration. A different response of the bacterial and archaeal community under ammonia stressed conditions was also observed. Under the high ammonia concentration, hydrogen-depended methylotrophic was the dominant methanogenesis route at OLR of 2.09 g VS Ld, while the hydrogenotrophic route was the dominant at the high OLR of 4 g VS Ld, which coincided with high acetate and propionate concentrations.

摘要

三个连续搅拌釜式反应器（CTSR）在有机负荷率（OLR）分别为 2.09、3.024 和 4.0 g VS L d 的稳定条件下运行。葡萄糖被用作提高 OLR 的唯一因素，将 OLR 的增加与 C/N 比的增加联系起来。通过将氨浓度从 1.862 g L 提高到 5 g L，对反应器施加了压力。结果表明，在高氨浓度下，仅通过增加 OLR 就会增加 C/N 比对厌氧过程的抑制作用。在氨胁迫条件下，细菌和古菌群落也表现出不同的反应。在高氨浓度下，氢依赖型甲基营养菌是 OLR 为 2.09 g VS L d 时的主要产甲烷途径，而氢营养型途径是 OLR 为 4 g VS L d 时的主要产甲烷途径，这与高乙酸和丙酸浓度相吻合。

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氨抑制不同有机负荷率下基于粪便的连续生物甲烷化过程及相关微生物群落动态。

Ammonia-induced inhibition of manure-based continuous biomethanation process under different organic loading rates and associated microbial community dynamics.

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