Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation

Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation

Abstract Tropical and subtropical acidic soils have been well documented as hotspots of global soil nitrogen (N) oxide (i.e., nitrous oxide (N2O) and nitric oxide (NO) emissions). While the effectiveness of possible mitigation options has been extensively examined in croplands, little is known about...

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Main Authors: Zhaoqiang Han, Jinyang Wang, Pinshang Xu, Zhutao Li, Shuwei Liu, Jianwen Zou
Format: Article
Language:English
Published: Wiley 2021-08-01
Series:GCB Bioenergy
Subjects:
acidic soil
climate‐smart practice
hotspots
mitigation option
sustainable agriculture
trace gas
Online Access:https://doi.org/10.1111/gcbb.12842
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spelling doaj-9247cb5bf4b540328e3ed0f7e4604acb2021-07-12T02:34:52ZengWileyGCB Bioenergy1757-16931757-17072021-08-011381260127410.1111/gcbb.12842Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantationZhaoqiang Han0Jinyang Wang1Pinshang Xu2Zhutao Li3Shuwei Liu4Jianwen Zou5Jiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaJiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaJiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaJiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaJiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaJiangsu Key Laboratory of Low Carbon Agriculture and GHGs Mitigation College of Resources and Environmental Sciences Nanjing Agricultural University Nanjing ChinaAbstract Tropical and subtropical acidic soils have been well documented as hotspots of global soil nitrogen (N) oxide (i.e., nitrous oxide (N2O) and nitric oxide (NO) emissions). While the effectiveness of possible mitigation options has been extensively examined in croplands, little is known about their effectiveness in reducing N‐oxide emissions from acidic soils of rapidly expanding tea plantations in China. Here, we conducted a 2‐year field experiment to investigate how organic substitution for synthetic fertilizer and biochar amendment affect soil N‐oxide emissions from a subtropical tea plantation. Across the 2‐year measurement period, full organic substitution for synthetic fertilizer significantly increased N2O emissions by an average of 17% while had a lower NO emission compared to synthetic fertilizer alone. Our global meta‐analysis further revealed that full or partial organic fertilizer substitution resulted in a 29% (95% confidence interval: 5%–60%) increase of N2O emissions from acidic soils. In contrast, irrespective of fertilizer type, biochar amendment significantly reduced N2O emissions by 14% in the first but not second experimental year, suggesting a transient effect. The trade‐off effect of full organic substitution on N2O and NO emissions may be attributed to the favorable conditions for N2O production due to the stimulated activity of nitrifiers and denitrifiers. The suppression of N2O emission following biochar amendment was probably due to promoted further reduction of N2O to dinitrogen. The fertilizer‐induced emission factor (EF) of N2O (2.1%) in the tea plantation was greater than the current IPCC default value, but the EF of NO (0.8%) was comparable to the global estimate. Taken together, while biochar amendment could have mitigation potential, cautions are needed when applying organic substitution for synthetic fertilizer as mitigation options for acidic soils as hotspots of N‐oxide emissions.https://doi.org/10.1111/gcbb.12842acidic soilclimate‐smart practicehotspotsmitigation optionsustainable agriculturetrace gas
collection DOAJ
language English
format Article
sources DOAJ
author Zhaoqiang Han
Jinyang Wang
Pinshang Xu
Zhutao Li
Shuwei Liu
Jianwen Zou
spellingShingle Zhaoqiang Han
Jinyang Wang
Pinshang Xu
Zhutao Li
Shuwei Liu
Jianwen Zou
Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
GCB Bioenergy
acidic soil
climate‐smart practice
hotspots
mitigation option
sustainable agriculture
trace gas
author_facet Zhaoqiang Han
Jinyang Wang
Pinshang Xu
Zhutao Li
Shuwei Liu
Jianwen Zou
author_sort Zhaoqiang Han
title Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
title_short Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
title_full Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
title_fullStr Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
title_full_unstemmed Differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
title_sort differential responses of soil nitrogen‐oxide emissions to organic substitution for synthetic fertilizer and biochar amendment in a subtropical tea plantation
publisher Wiley
series GCB Bioenergy
issn 1757-1693
1757-1707
publishDate 2021-08-01
description Abstract Tropical and subtropical acidic soils have been well documented as hotspots of global soil nitrogen (N) oxide (i.e., nitrous oxide (N2O) and nitric oxide (NO) emissions). While the effectiveness of possible mitigation options has been extensively examined in croplands, little is known about their effectiveness in reducing N‐oxide emissions from acidic soils of rapidly expanding tea plantations in China. Here, we conducted a 2‐year field experiment to investigate how organic substitution for synthetic fertilizer and biochar amendment affect soil N‐oxide emissions from a subtropical tea plantation. Across the 2‐year measurement period, full organic substitution for synthetic fertilizer significantly increased N2O emissions by an average of 17% while had a lower NO emission compared to synthetic fertilizer alone. Our global meta‐analysis further revealed that full or partial organic fertilizer substitution resulted in a 29% (95% confidence interval: 5%–60%) increase of N2O emissions from acidic soils. In contrast, irrespective of fertilizer type, biochar amendment significantly reduced N2O emissions by 14% in the first but not second experimental year, suggesting a transient effect. The trade‐off effect of full organic substitution on N2O and NO emissions may be attributed to the favorable conditions for N2O production due to the stimulated activity of nitrifiers and denitrifiers. The suppression of N2O emission following biochar amendment was probably due to promoted further reduction of N2O to dinitrogen. The fertilizer‐induced emission factor (EF) of N2O (2.1%) in the tea plantation was greater than the current IPCC default value, but the EF of NO (0.8%) was comparable to the global estimate. Taken together, while biochar amendment could have mitigation potential, cautions are needed when applying organic substitution for synthetic fertilizer as mitigation options for acidic soils as hotspots of N‐oxide emissions.
topic acidic soil
climate‐smart practice
hotspots
mitigation option
sustainable agriculture
trace gas
url https://doi.org/10.1111/gcbb.12842
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AT jinyangwang differentialresponsesofsoilnitrogenoxideemissionstoorganicsubstitutionforsyntheticfertilizerandbiocharamendmentinasubtropicalteaplantation
AT pinshangxu differentialresponsesofsoilnitrogenoxideemissionstoorganicsubstitutionforsyntheticfertilizerandbiocharamendmentinasubtropicalteaplantation
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AT shuweiliu differentialresponsesofsoilnitrogenoxideemissionstoorganicsubstitutionforsyntheticfertilizerandbiocharamendmentinasubtropicalteaplantation
AT jianwenzou differentialresponsesofsoilnitrogenoxideemissionstoorganicsubstitutionforsyntheticfertilizerandbiocharamendmentinasubtropicalteaplantation
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