Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland

Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland

Background Di-nitrogen oxide (N2O) emissions from soil may lead to nonpoint-source pollution in farmland. Improving the C and N content in the soil is an excellent strategy to reduce N2O emission and mitigate soil N loss. However, this method lacks a unified mathematical index or standard to evaluat...

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Main Authors: Xiao Wang, Ping Lu, Peiling Yang, Shumei Ren
Format: Article
Language:English
Published: PeerJ Inc. 2021-07-01
Series:PeerJ
Subjects:
Biochar
N2O emissions
Soil moisture
Soil temperature
Fertilization
Sensitivity coefficient
Online Access:https://peerj.com/articles/11674.pdf
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spelling doaj-04981d2ae60842429d49f8bc8bc127df2021-07-22T15:05:05ZengPeerJ Inc.PeerJ2167-83592021-07-019e1167410.7717/peerj.11674Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmlandXiao Wang0Ping Lu1Peiling Yang2Shumei Ren3College of Water Resources and Civil Engineering, China Agricultural University, Beijing, ChinaCollege of Sericulture, Textile and Biomass Sciences, Southwest University, Chongqing, ChinaCollege of Water Resources and Civil Engineering, China Agricultural University, Beijing, ChinaCollege of Water Resources and Civil Engineering, China Agricultural University, Beijing, ChinaBackground Di-nitrogen oxide (N2O) emissions from soil may lead to nonpoint-source pollution in farmland. Improving the C and N content in the soil is an excellent strategy to reduce N2O emission and mitigate soil N loss. However, this method lacks a unified mathematical index or standard to evaluate its effect. Methods To quantify the impact of soil improvement (C and N) on N2O emissions, we conducted a 2-year field experiment using biochar as carbon source and fertilizer as nitrogen source, setting three treatments (fertilization (300 kg N ha−1), fertilization + biochar (30 t ha−1), control). Results Results indicate that after biochar application, the average soil water content above 20 cm increased by ∼26% and 26.92% in 2019, and ∼10% and 12.49% in 2020. The average soil temperature above 20 cm also increased by ∼2% and 3.41% in 2019. Fertigation significantly promotes the soil N2O emissions, and biochar application indeed inhibited the cumulation by approximately 52.4% in 2019 and 33.9% in 2020, respectively. N2O emissions strongly depend on the deep soil moisture and temperature (20–80 cm), in addition to the surface soil moisture and temperature (0–20 cm). Therefore, we established an exponential model between the soil moisture and N2O emissions based on theoretical analysis. We find that the N2O emissions exponentially increase with increasing soil moisture regardless of fertilization or biochar application. Furthermore, the coefficient a < 0 means that N2O emissions initially increase and then decrease. The aRU < aCK indicates that fertilization does promote the rate of N2O emissions, and the aBRU > aRU indicates that biochar application mitigates this rate induced by fertilization. This conclusion can be verified by the sensitivity coefficient (SCB of 1.02 and 14.74; SCU of 19.18 and 20.83). Thus, we believe the model can quantify the impact of soil C and N changes on N2O emissions. We can conclude that biochar does significantly reduce N2O emissions from farmland.https://peerj.com/articles/11674.pdfBiocharN2O emissionsSoil moistureSoil temperatureFertilizationSensitivity coefficient
collection DOAJ
language English
format Article
sources DOAJ
author Xiao Wang
Ping Lu
Peiling Yang
Shumei Ren
spellingShingle Xiao Wang
Ping Lu
Peiling Yang
Shumei Ren
Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
PeerJ
Biochar
N2O emissions
Soil moisture
Soil temperature
Fertilization
Sensitivity coefficient
author_facet Xiao Wang
Ping Lu
Peiling Yang
Shumei Ren
author_sort Xiao Wang
title Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
title_short Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
title_full Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
title_fullStr Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
title_full_unstemmed Effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and N2O emissions in farmland
title_sort effects of fertilizer and biochar applications on the relationship among soil moisture, temperature, and n2o emissions in farmland
publisher PeerJ Inc.
series PeerJ
issn 2167-8359
publishDate 2021-07-01
description Background Di-nitrogen oxide (N2O) emissions from soil may lead to nonpoint-source pollution in farmland. Improving the C and N content in the soil is an excellent strategy to reduce N2O emission and mitigate soil N loss. However, this method lacks a unified mathematical index or standard to evaluate its effect. Methods To quantify the impact of soil improvement (C and N) on N2O emissions, we conducted a 2-year field experiment using biochar as carbon source and fertilizer as nitrogen source, setting three treatments (fertilization (300 kg N ha−1), fertilization + biochar (30 t ha−1), control). Results Results indicate that after biochar application, the average soil water content above 20 cm increased by ∼26% and 26.92% in 2019, and ∼10% and 12.49% in 2020. The average soil temperature above 20 cm also increased by ∼2% and 3.41% in 2019. Fertigation significantly promotes the soil N2O emissions, and biochar application indeed inhibited the cumulation by approximately 52.4% in 2019 and 33.9% in 2020, respectively. N2O emissions strongly depend on the deep soil moisture and temperature (20–80 cm), in addition to the surface soil moisture and temperature (0–20 cm). Therefore, we established an exponential model between the soil moisture and N2O emissions based on theoretical analysis. We find that the N2O emissions exponentially increase with increasing soil moisture regardless of fertilization or biochar application. Furthermore, the coefficient a < 0 means that N2O emissions initially increase and then decrease. The aRU < aCK indicates that fertilization does promote the rate of N2O emissions, and the aBRU > aRU indicates that biochar application mitigates this rate induced by fertilization. This conclusion can be verified by the sensitivity coefficient (SCB of 1.02 and 14.74; SCU of 19.18 and 20.83). Thus, we believe the model can quantify the impact of soil C and N changes on N2O emissions. We can conclude that biochar does significantly reduce N2O emissions from farmland.
topic Biochar
N2O emissions
Soil moisture
Soil temperature
Fertilization
Sensitivity coefficient
url https://peerj.com/articles/11674.pdf
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