Impact of biochar on mineralisation of C and N from soil and willow litter and its relationship with microbial community biomass and structure
Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO₂ mi...
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Published in | Biology and fertility of soils Vol. 50; no. 4; pp. 695 - 702 |
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Main Authors | , , , |
Format | Journal Article |
Language | English |
Published |
Berlin/Heidelberg
Springer-Verlag
01.05.2014
Springer Berlin Heidelberg Springer Springer Nature B.V |
Subjects | |
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Abstract | Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO₂ mineralisation in the presence or absence of litter. However at a rate of 2 %, net CO₂ mineralisation was reduced by 10 and 20 % over a 90-day period in the absence and presence of litter respectively. Biochar reduced N mineralisation when applied at both 0.5 and 2 % concentrations. pH was increased by application of 2 % biochar to soil. Phospholipid fatty acid analysis demonstrated that both concentrations of biochar affected microbial community composition, although the effect of biochar was not as great as the effect of time or litter application in shaping community structure. In particular, the amount of bacterial biomass was increased by biochar application to soil, and there was evidence for increased abundance of Gram-negative bacteria and actinobacteria following biochar application. The data is discussed in the context of microbial mechanisms underlying impacts of biochar on C cycling in soil, and the coupling of C and N cycles following amendment of soil with biochar. |
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AbstractList | Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO
2
mineralisation in the presence or absence of litter. However at a rate of 2 %, net CO
2
mineralisation was reduced by 10 and 20 % over a 90-day period in the absence and presence of litter respectively. Biochar reduced N mineralisation when applied at both 0.5 and 2 % concentrations. pH was increased by application of 2 % biochar to soil. Phospholipid fatty acid analysis demonstrated that both concentrations of biochar affected microbial community composition, although the effect of biochar was not as great as the effect of time or litter application in shaping community structure. In particular, the amount of bacterial biomass was increased by biochar application to soil, and there was evidence for increased abundance of Gram-negative bacteria and actinobacteria following biochar application. The data is discussed in the context of microbial mechanisms underlying impacts of biochar on C cycling in soil, and the coupling of C and N cycles following amendment of soil with biochar. Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO sub(2) mineralisation in the presence or absence of litter. However at a rate of 2 %, net CO sub(2) mineralisation was reduced by 10 and 20 % over a 90-day period in the absence and presence of litter respectively. Biochar reduced N mineralisation when applied at both 0.5 and 2 % concentrations. pH was increased by application of 2 % biochar to soil. Phospholipid fatty acid analysis demonstrated that both concentrations of biochar affected microbial community composition, although the effect of biochar was not as great as the effect of time or litter application in shaping community structure. In particular, the amount of bacterial biomass was increased by biochar application to soil, and there was evidence for increased abundance of Gram-negative bacteria and actinobacteria following biochar application. The data is discussed in the context of microbial mechanisms underlying impacts of biochar on C cycling in soil, and the coupling of C and N cycles following amendment of soil with biochar. Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO₂ mineralisation in the presence or absence of litter. However at a rate of 2 %, net CO₂ mineralisation was reduced by 10 and 20 % over a 90-day period in the absence and presence of litter respectively. Biochar reduced N mineralisation when applied at both 0.5 and 2 % concentrations. pH was increased by application of 2 % biochar to soil. Phospholipid fatty acid analysis demonstrated that both concentrations of biochar affected microbial community composition, although the effect of biochar was not as great as the effect of time or litter application in shaping community structure. In particular, the amount of bacterial biomass was increased by biochar application to soil, and there was evidence for increased abundance of Gram-negative bacteria and actinobacteria following biochar application. The data is discussed in the context of microbial mechanisms underlying impacts of biochar on C cycling in soil, and the coupling of C and N cycles following amendment of soil with biochar. Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass and community composition, in the presence and absence of willow litter. Application of biochar at a rate of 0.5 % had no effect on net CO2 mineralisation in the presence or absence of litter. However at a rate of 2 %, net CO2 mineralisation was reduced by 10 and 20 % over a 90-day period in the absence and presence of litter respectively. Biochar reduced N mineralisation when applied at both 0.5 and 2 % concentrations. pH was increased by application of 2 % biochar to soil. Phospholipid fatty acid analysis demonstrated that both concentrations of biochar affected microbial community composition, although the effect of biochar was not as great as the effect of time or litter application in shaping community structure. In particular, the amount of bacterial biomass was increased by biochar application to soil, and there was evidence for increased abundance of Gram-negative bacteria and actinobacteria following biochar application. The data is discussed in the context of microbial mechanisms underlying impacts of biochar on C cycling in soil, and the coupling of C and N cycles following amendment of soil with biochar.[PUBLICATION ABSTRACT] |
Author | Prayogo, Cahyo Bending, Gary D Jones, Julie E Baeyens, Jan |
Author_xml | – sequence: 1 fullname: Prayogo, Cahyo – sequence: 2 fullname: Jones, Julie E – sequence: 3 fullname: Baeyens, Jan – sequence: 4 fullname: Bending, Gary D |
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Issue | 4 |
Keywords | PLFA Decomposition Litter Biochar Mineralisation Phospholipid Nitrogen Fatty acids Microbial biomass Carbon Carbonization Soils Mineralization Soil science Microbial community |
Language | English |
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PublicationSubtitle | Cooperating Journal of International Society of Soil Science |
PublicationTitle | Biology and fertility of soils |
PublicationTitleAbbrev | Biol Fertil Soils |
PublicationYear | 2014 |
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Snippet | Using a laboratory experiment, we investigated the effect of applying willow biochar to short rotation coppice soil on C and N dynamics and microbial biomass... |
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SubjectTerms | Actinobacteria Agriculture Agronomy. Soil science and plant productions Bacteria biochar Biochemistry and biology Biological and medical sciences Biomass Biomedical and Life Sciences Carbon Carbon dioxide Charcoal Chemical, physicochemical, biochemical and biological properties Community composition Community structure Decomposition fatty acids Fundamental and applied biological sciences. Psychology Gram-negative bacteria laboratory experimentation Life Sciences Litter microbial biomass microbial communities Microbiology Mineralization Mineralogy Nitrogen Original Paper Physics, chemistry, biochemistry and biology of agricultural and forest soils soil Soil amendment soil amendments Soil fertility Soil science Soil Science & Conservation soil treatment |
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Title | Impact of biochar on mineralisation of C and N from soil and willow litter and its relationship with microbial community biomass and structure |
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