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湖泊微生物硝化过程研究进展 被引量:6

Research progress in microbial nitrification in lakes
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摘要 湖泊中微生物介导的硝化作用在生境内部氮周转和温室气体N2O释放方面扮演着关键的角色。因此,研究湖泊微生物硝化过程及速率有助于我们整体评估湖泊生境内部的氮循环状态,全面认识湖泊响应区域乃至全球气候变化的规律。本文综述了湖泊生境中硝化过程及其驱动微生物和影响因素,包括氨氧化过程、亚硝酸盐氧化过程和完全氨氧化过程,同时聚焦前沿,归纳了氨氧化古菌、氨氧化细菌和完全氨氧化菌产生N2O的机制和相对贡献。最后对湖泊硝化过程研究现状和未来发展方向提出总结和展望。 Microbially mediated nitrification plays a key role in nitrogen transformation and emission of greenhouse gases N2O in lacustrine ecosystems.Thus,studying microbial nitrification process and rate in lake environments helps comprehensively understand nitrogen biogeochemical cycle in lacustrine ecosystems and its response to regional and global climate change.This review summarized processes and microbial community compositions of nitrification(including ammonia oxidation,nitrite oxidation and complete ammonia oxidation)in lacustrine ecosystems and their influencing factors.Spotlight was given to the mechanisms and relative contributions of N2O production through ammonia oxidizing archaea and bacteria and complete ammonia oxidizing bacteria,followed by summary and prospect on the current situation and future development of nitrification researches in lakes.
作者 孙小溪 蒋宏忱 Xiaoxi Sun;Hongchen Jiang(State Key Laboratory of Biogeology and Environmental Geology,China University of Geosciences,Wuhan 430074,HubeiProvince,China)
机构地区 中国地质大学(武汉)
出处 《微生物学报》 CAS CSCD 北大核心 2020年第6期1148-1161,共14页 Acta Microbiologica Sinica
基金 国家自然科学基金(91751206) 中央高校基本科研业务费专项。
关键词 湖泊 微生物 硝化 N2O 影响因素 lakes microbes nitrification N2O influencing factors
分类号 Q938 [生物学—微生物学]
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微生物学报
2020年 第6期

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