Elucidating the Impacts of Biochar Applications on Nitrogen Cycling Microbial Communities

N. Hagemann; J. Harter; S. Behrens

doi:10.1016/B978-0-12-803433-0.00007-2

Elucidating the Impacts of Biochar Applications on Nitrogen Cycling Microbial Communities

N. Hagemann, J. Harter, S. Behrens

Civil, Environmental, and Geo- Engineering

Research output: Chapter in Book/Report/Conference proceeding › Chapter

42 Scopus citations

Abstract

Biochar has been shown to improve soil function through increased cation and anion exchange capacity, soil water retention, increased soil buffer capacity, and enhanced microbial growth. Proposed mechanisms by which biochar will increase microbial activity include provision of labile carbon, increased nutrient retention, facilitated electron transfer (shuttling) to microorganisms, and increased microbial habitat space given the high specific surface area and micropore volume of biochar. Furthermore, some studies have shown that it reduces N₂O emissions during denitrification in soils. Here we discuss the impact of biochar amendment on soil microbial nitrogen cycling.

Original language	English (US)
Title of host publication	Biochar Application
Subtitle of host publication	Essential Soil Microbial Ecology
Publisher	Elsevier Inc.
Pages	163-198
Number of pages	36
ISBN (Electronic)	9780128034361
ISBN (Print)	9780128034330
DOIs	https://doi.org/10.1016/B978-0-12-803433-0.00007-2
State	Published - May 25 2016

Bibliographical note

Publisher Copyright:
© 2016 Elsevier Inc. All rights reserved.

Keywords

Ammonification
Denitrification
Immobilization
Leaching
Mineralization
Nitrification
Nitrogen fixation
Nitrous oxide
Redox cycling
Water-filled pore space

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abstract = "Biochar has been shown to improve soil function through increased cation and anion exchange capacity, soil water retention, increased soil buffer capacity, and enhanced microbial growth. Proposed mechanisms by which biochar will increase microbial activity include provision of labile carbon, increased nutrient retention, facilitated electron transfer (shuttling) to microorganisms, and increased microbial habitat space given the high specific surface area and micropore volume of biochar. Furthermore, some studies have shown that it reduces N2O emissions during denitrification in soils. Here we discuss the impact of biochar amendment on soil microbial nitrogen cycling.",

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AU - Harter, J.

AU - Behrens, S.

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AB - Biochar has been shown to improve soil function through increased cation and anion exchange capacity, soil water retention, increased soil buffer capacity, and enhanced microbial growth. Proposed mechanisms by which biochar will increase microbial activity include provision of labile carbon, increased nutrient retention, facilitated electron transfer (shuttling) to microorganisms, and increased microbial habitat space given the high specific surface area and micropore volume of biochar. Furthermore, some studies have shown that it reduces N2O emissions during denitrification in soils. Here we discuss the impact of biochar amendment on soil microbial nitrogen cycling.

KW - Ammonification

KW - Denitrification

KW - Immobilization

KW - Leaching

KW - Mineralization

KW - Nitrification

KW - Nitrogen fixation

KW - Nitrous oxide

KW - Redox cycling

KW - Water-filled pore space

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Elucidating the Impacts of Biochar Applications on Nitrogen Cycling Microbial Communities

Abstract

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Keywords

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