Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed

Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed

Abstract Background Soil organic carbon (SOC) plays a crucial role in the global carbon cycle and terrestrial ecosystem functions. It is widely known that climate change and soil water content (SWC) could influence the SOC dynamics; however, there are still debates about how climate change, especial...

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Main Authors: Fubo Zhao, Yiping Wu, Jinyu Hui, Bellie Sivakumar, Xianyong Meng, Shuguang Liu
Format: Article
Language:English
Published: BMC 2021-08-01
Series:Carbon Balance and Management
Subjects:
Carbon cycle
Climate change
Soil organic carbon
Soil water content
SWAT-DayCent
Online Access:https://doi.org/10.1186/s13021-021-00187-2
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spelling doaj-a655a6f3b263490b9a58c3a7d69e75b42021-08-22T11:18:44ZengBMCCarbon Balance and Management1750-06802021-08-0116111410.1186/s13021-021-00187-2Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershedFubo Zhao0Yiping Wu1Jinyu Hui2Bellie Sivakumar3Xianyong Meng4Shuguang Liu5Department of Earth & Environmental Science, School of Human Settlements and Civil Engineering, Xi’an Jiaotong UniversityDepartment of Earth & Environmental Science, School of Human Settlements and Civil Engineering, Xi’an Jiaotong UniversityDepartment of Earth & Environmental Science, School of Human Settlements and Civil Engineering, Xi’an Jiaotong UniversityDepartment of Civil Engineering, Indian Institute of Technology BombayCollege of Resources and Environmental Sciences, China Agricultural UniversityNational Engineering Laboratory for Applied Technology of Forestry and Ecology in South China, Central South University of Forestry and TechnologyAbstract Background Soil organic carbon (SOC) plays a crucial role in the global carbon cycle and terrestrial ecosystem functions. It is widely known that climate change and soil water content (SWC) could influence the SOC dynamics; however, there are still debates about how climate change, especially climate warming, and SWC impact SOC. We investigated the spatiotemporal changes in SOC and its responses to climate warming and root-zone SWC change using the coupled hydro-biogeochemical model (SWAT-DayCent) and climate scenarios data derived under the three Representative Concentration Pathways (RCPs2.6, 4.5, and 8.5) from five downscaled Global Climate Models (GCMs) in a typical loess watershed––the Jinghe River Basin (JRB) on the Chinese Loess Plateau. Results The air temperature would increase significantly during the future period (2017–2099), while the annual precipitation would increase by 2.0–13.1% relative to the baseline period (1976–2016), indicating a warmer and wetter future in the JRB. Driven by the precipitation variation, the root-zone SWC would also increase (by up to 27.9% relative to the baseline under RCP4.5); however, the SOC was projected to decrease significantly under the future warming climate. The combined effects of climate warming and SWC change could more reasonably explain the SOC loss, and this formed hump-shaped response surfaces between SOC loss and warming-SWC interactions under both RCP2.6 and 8.5, which can help explain diverse warming effects on SOC with changing SWC. Conclusions The study showed a significant potential carbon source under the future warmer and wetter climate in the JRB, and the SOC loss was largely controlled by future climate warming and the root-zone SWC as well. The hump-shaped responses of the SOC loss to climate warming and SWC change demonstrated that the SWC could mediate the warming effects on SOC loss, but this mediation largely depended on the SWC changing magnitude (drier or wetter soil conditions). This mediation mechanism about the effect of SWC on SOC would be valuable for enhancing soil carbon sequestration in a warming climate on the Loess Plateau.https://doi.org/10.1186/s13021-021-00187-2Carbon cycleClimate changeSoil organic carbonSoil water contentSWAT-DayCent
collection DOAJ
language English
format Article
sources DOAJ
author Fubo Zhao
Yiping Wu
Jinyu Hui
Bellie Sivakumar
Xianyong Meng
Shuguang Liu
spellingShingle Fubo Zhao
Yiping Wu
Jinyu Hui
Bellie Sivakumar
Xianyong Meng
Shuguang Liu
Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
Carbon Balance and Management
Carbon cycle
Climate change
Soil organic carbon
Soil water content
SWAT-DayCent
author_facet Fubo Zhao
Yiping Wu
Jinyu Hui
Bellie Sivakumar
Xianyong Meng
Shuguang Liu
author_sort Fubo Zhao
title Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
title_short Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
title_full Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
title_fullStr Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
title_full_unstemmed Projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
title_sort projected soil organic carbon loss in response to climate warming and soil water content in a loess watershed
publisher BMC
series Carbon Balance and Management
issn 1750-0680
publishDate 2021-08-01
description Abstract Background Soil organic carbon (SOC) plays a crucial role in the global carbon cycle and terrestrial ecosystem functions. It is widely known that climate change and soil water content (SWC) could influence the SOC dynamics; however, there are still debates about how climate change, especially climate warming, and SWC impact SOC. We investigated the spatiotemporal changes in SOC and its responses to climate warming and root-zone SWC change using the coupled hydro-biogeochemical model (SWAT-DayCent) and climate scenarios data derived under the three Representative Concentration Pathways (RCPs2.6, 4.5, and 8.5) from five downscaled Global Climate Models (GCMs) in a typical loess watershed––the Jinghe River Basin (JRB) on the Chinese Loess Plateau. Results The air temperature would increase significantly during the future period (2017–2099), while the annual precipitation would increase by 2.0–13.1% relative to the baseline period (1976–2016), indicating a warmer and wetter future in the JRB. Driven by the precipitation variation, the root-zone SWC would also increase (by up to 27.9% relative to the baseline under RCP4.5); however, the SOC was projected to decrease significantly under the future warming climate. The combined effects of climate warming and SWC change could more reasonably explain the SOC loss, and this formed hump-shaped response surfaces between SOC loss and warming-SWC interactions under both RCP2.6 and 8.5, which can help explain diverse warming effects on SOC with changing SWC. Conclusions The study showed a significant potential carbon source under the future warmer and wetter climate in the JRB, and the SOC loss was largely controlled by future climate warming and the root-zone SWC as well. The hump-shaped responses of the SOC loss to climate warming and SWC change demonstrated that the SWC could mediate the warming effects on SOC loss, but this mediation largely depended on the SWC changing magnitude (drier or wetter soil conditions). This mediation mechanism about the effect of SWC on SOC would be valuable for enhancing soil carbon sequestration in a warming climate on the Loess Plateau.
topic Carbon cycle
Climate change
Soil organic carbon
Soil water content
SWAT-DayCent
url https://doi.org/10.1186/s13021-021-00187-2
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