Impacts of adding FeSO4 and biochar on nitrogen loss, bacterial community and related functional genes during cattle manure composting

•The addition of biochar and FeSO4 reduce NH3 and N2O emissions by 52.4 and 35.6%.•The addition of biochar and FeSO4 increased the abundance of amoA and narG.•Biochar and FeSO4 addition mitigate nitrogen loss by affecting the nitrogen flux. This study investigated the impacts of adding FeSO4 and bio...

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Published inBioresource technology Vol. 379; p. 129029
Main Authors Liu, Zhuangzhuang, Yan, Zhiwei, Liu, Gang, Wang, Xinyu, Fang, Jun
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.07.2023
Subjects
Actinobacteria
bacterial communities
Bacterial community
biochar
cattle manure
Composting
denitrification
genes
nitrification
nitrogen
Nitrogen functional gene
Nitrogen loss
Proteobacteria
rice straw
technology
total nitrogen
Composting
Nitrogen loss
Nitrogen functional gene
Bacterial community
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Abstract •The addition of biochar and FeSO4 reduce NH3 and N2O emissions by 52.4 and 35.6%.•The addition of biochar and FeSO4 increased the abundance of amoA and narG.•Biochar and FeSO4 addition mitigate nitrogen loss by affecting the nitrogen flux. This study investigated the impacts of adding FeSO4 and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss, bacterial community, nitrification, and denitrification. Four treatments were established, including a control group (CP), and CP mixtures that included 4% biochar (TG1), 4% FeSO4 (TG2), or 2% FeSO4 and 2% biochar (TG3). Compared to CP, TG1–3 had a lower total nitrogen loss rate, and TG3 resulted in reduced NH3 (52.4%) and N2O (35.6%) emissions to mitigate nitrogen loss. The abundance of amoA and narG gene in TG3 was higher than in the other groups, and TG3 was beneficial to the growth of Proteobacteria and Actinobacteria. According to redundancy and Pearson analysis, TG3 had a positive effect on the nitrification process by increasing the abundance of amoA and narG. Thus, biochar and FeSO4 addition mitigate nitrogen loss by regulating the nitrification processes.
AbstractList This study investigated the impacts of adding FeSO₄ and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss, bacterial community, nitrification, and denitrification. Four treatments were established, including a control group (CP), and CP mixtures that included 4% biochar (TG1), 4% FeSO₄ (TG2), or 2% FeSO₄ and 2% biochar (TG3). Compared to CP, TG1–3 had a lower total nitrogen loss rate, and TG3 resulted in reduced NH₃ (52.4%) and N₂O (35.6%) emissions to mitigate nitrogen loss. The abundance of amoA and narG gene in TG3 was higher than in the other groups, and TG3 was beneficial to the growth of Proteobacteria and Actinobacteria. According to redundancy and Pearson analysis, TG3 had a positive effect on the nitrification process by increasing the abundance of amoA and narG. Thus, biochar and FeSO₄ addition mitigate nitrogen loss by regulating the nitrification processes.
This study investigated the impacts of adding FeSO4 and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss, bacterial community, nitrification, and denitrification. Four treatments were established, including a control group (CP), and CP mixtures that included 4% biochar (TG1), 4% FeSO4 (TG2), or 2% FeSO4 and 2% biochar (TG3). Compared to CP, TG1-3 had a lower total nitrogen loss rate, and TG3 resulted in reduced NH3 (52.4%) and N2O (35.6%) emissions to mitigate nitrogen loss. The abundance of amoA and narG gene in TG3 was higher than in the other groups, and TG3 was beneficial to the growth of Proteobacteria and Actinobacteria. According to redundancy and Pearson analysis, TG3 had a positive effect on the nitrification process by increasing the abundance of amoA and narG. Thus, biochar and FeSO4 addition mitigate nitrogen loss by regulating the nitrification processes.This study investigated the impacts of adding FeSO4 and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss, bacterial community, nitrification, and denitrification. Four treatments were established, including a control group (CP), and CP mixtures that included 4% biochar (TG1), 4% FeSO4 (TG2), or 2% FeSO4 and 2% biochar (TG3). Compared to CP, TG1-3 had a lower total nitrogen loss rate, and TG3 resulted in reduced NH3 (52.4%) and N2O (35.6%) emissions to mitigate nitrogen loss. The abundance of amoA and narG gene in TG3 was higher than in the other groups, and TG3 was beneficial to the growth of Proteobacteria and Actinobacteria. According to redundancy and Pearson analysis, TG3 had a positive effect on the nitrification process by increasing the abundance of amoA and narG. Thus, biochar and FeSO4 addition mitigate nitrogen loss by regulating the nitrification processes.
•The addition of biochar and FeSO4 reduce NH3 and N2O emissions by 52.4 and 35.6%.•The addition of biochar and FeSO4 increased the abundance of amoA and narG.•Biochar and FeSO4 addition mitigate nitrogen loss by affecting the nitrogen flux. This study investigated the impacts of adding FeSO4 and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss, bacterial community, nitrification, and denitrification. Four treatments were established, including a control group (CP), and CP mixtures that included 4% biochar (TG1), 4% FeSO4 (TG2), or 2% FeSO4 and 2% biochar (TG3). Compared to CP, TG1–3 had a lower total nitrogen loss rate, and TG3 resulted in reduced NH3 (52.4%) and N2O (35.6%) emissions to mitigate nitrogen loss. The abundance of amoA and narG gene in TG3 was higher than in the other groups, and TG3 was beneficial to the growth of Proteobacteria and Actinobacteria. According to redundancy and Pearson analysis, TG3 had a positive effect on the nitrification process by increasing the abundance of amoA and narG. Thus, biochar and FeSO4 addition mitigate nitrogen loss by regulating the nitrification processes.
ArticleNumber 129029
Author Liu, Gang
Yan, Zhiwei
Liu, Zhuangzhuang
Wang, Xinyu
Fang, Jun
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  organization: College of Bioscience and Biotechnology, Hunan Agricultural University, Changsha, Hunan 410128, PR China
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  givenname: Jun
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Nitrogen loss
Nitrogen functional gene
Bacterial community
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Snippet •The addition of biochar and FeSO4 reduce NH3 and N2O emissions by 52.4 and 35.6%.•The addition of biochar and FeSO4 increased the abundance of amoA and...
This study investigated the impacts of adding FeSO4 and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss,...
This study investigated the impacts of adding FeSO₄ and biochar to cattle manure and rice straw composts on functional genes controlling nitrogen loss,...
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SubjectTerms Actinobacteria
bacterial communities
Bacterial community
biochar
cattle manure
Composting
denitrification
genes
nitrification
nitrogen
Nitrogen functional gene
Nitrogen loss
Proteobacteria
rice straw
technology
total nitrogen
Title Impacts of adding FeSO4 and biochar on nitrogen loss, bacterial community and related functional genes during cattle manure composting
URI https://dx.doi.org/10.1016/j.biortech.2023.129029
https://www.proquest.com/docview/2798714408
https://www.proquest.com/docview/2834203149
Volume 379
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