Your search keyword '"Shuwei Liu"' showing total 12 results

1. The role of rice cultivation in changes in atmospheric methane concentration and the Global Methane Pledge.

Author

Jinyang Wang, Ciais, Philippe, Smith, Pete, Xiaoyuan Yan, Yakov Kuzyakov, Shuwei Liu, Tingting Li, and Jianwen Zou

Subjects

ATMOSPHERIC methane, RICE, PADDY fields, METHANE, WATER management, GREENHOUSE gases, AIR quality management

Abstract

Resumption of the increase in atmospheric methane (CH4) concentrations since 2007 is of global concern and may partly have resulted from emissions from rice cultivation. Estimates of CH4 emissions from rice fields and abatement potential are essential to assess the contribution of improved rice management in achieving the targets of the Global Methane Pledge agreed upon by over 100 countries at COP26. However, the contribution of CH4 emissions from rice fields to the resumed CH4 growth and the global abatement potential remains unclear. In this study, we estimated the global CH4 emissions from rice fields to be 27 ± 6 Tg CH4 year-1 in the recent decade (2008-2017) based on the 2019 Refinement to the 2006 IPCC Guidelines for National Greenhouse Gas Inventories. The trend of CH4 emissions from rice cultivation showed an increase followed by no significant change and then, a stabilization over 1990-2020. Consequently, the contribution of CH4 emissions from rice fields to the renewed increase in atmospheric CH4 concentrations since 2007 was minor. We summarized the existing low-cost measures and showed that improved water and straw management could reduce one-third of global CH4 emissions from rice fields. Straw returned as biochar could reduce CH4 emissions by 12 Tg CH4 year-1, equivalent to 10% of the total reduction of all anthropogenic emissions. We conclude that other sectors than rice cultivation must have contributed to the renewed increase in atmospheric CH4 concentrations, and that optimizing multiple mitigation measures in rice fields could contribute significantly to the abatement goal outlined in the Global Methane Pledge. [ABSTRACT FROM AUTHOR]

Published

2023

2. Global methane and nitrous oxide emissions from inland waters and estuaries

Author

Yajing Zheng, Shuang Wu, Shuqi Xiao, Kai Yu, Xiantao Fang, Longlong Xia, Jinyang Wang, Shuwei Liu, Chris Freeman, and Jianwen Zou

Subjects

Greenhouse Gases, Global and Planetary Change, Ecology, Nitrous Oxide, Environmental Chemistry, Carbon Dioxide, Estuaries, Methane, General Environmental Science

Abstract

Inland waters (rivers, reservoirs, lakes, ponds, streams) and estuaries are significant emitters of methane (CH

Published

2022

3. Data‐driven estimates of fertilizer‐induced soil NH 3 , NO and N 2 O emissions from croplands in China and their climate change impacts

Author

Ruoya Ma, Shuqi Xiao, Jianwen Zou, Philippe Ciais, Shuwei Liu, Kai Yu, Laboratoire des Sciences du Climat et de l'Environnement [Gif-sur-Yvette] (LSCE), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Jiangsu Agricultural Science and Technology Innovation Fund, JASTIF: JASTIF‐CX(21)3007, National Natural Science Foundation of China, NSFC: 42077080, Natural Science Foundation of Jiangsu Province for Distinguished Young Scholars: BK20200024, and This work was supported by the National Natural Science Foundation of China (42077080), Natural Science Foundation of Jiangsu Province for Distinguished Young Scholars (BK20200024), and Jiangsu Agriculture Science and Technology Innovation Fund [JASTIF‐CX(21)3007]. We are grateful to many researchers who measured soil NH, NO and NO fluxes and other target parameters. Their work is the basis of the present data integration and extrapolation. 3 2

Subjects

emission factor, Reactive nitrogen, [SDE.MCG]Environmental Sciences/Global Changes, Climate change, reactive nitrogen, engineering.material, nitrogen use efficiency, chemistry.chemical_compound, Environmental protection, Environmental Chemistry, General Environmental Science, Global and Planetary Change, Ecology, business.industry, Global warming, Nitrous oxide, fertilizer, Manure, climate change, chemistry, Agriculture, Soil water, engineering, Environmental science, Fertilizer, business

Abstract

International audience; Gaseous reactive nitrogen (Nr) emissions from agricultural soils to the atmosphere constitute an integral part of global N cycle, directly or indirectly causing climate change impacts. The extensive use of N fertilizer in crop production will compromise our efforts to reduce agricultural Nr emissions in China. A national inventory of fertilizer N-induced gaseous Nr emissions from croplands in China remains to be developed to reveal its role in shaping climate change. Here we present a data-driven estimate of fertilizer N-induced soil Nr emissions based on regional and crop-specific emission factors (EFs) compiled from 379 manipulative studies. In China, agricultural soil Nr emissions from the use of synthetic N fertilizer and manure in 2018 are estimated to be 3.81 and 0.73 Tg N yr−1, with a combined contribution of 23%, 20% and 15% to the global agricultural emission total of ammonia (NH3), nitrous oxide (N2O) and nitric oxide (NO), respectively. Over the past three decades, NH3 volatilization from croplands has experienced a shift from a rapid increase to a decline trend, whereas N2O and NO emissions always maintain a strong growth momentum due to a robust and continuous rise of EFs. Regionally, croplands in Central south (1.51 Tg N yr−1) and East (0.99 Tg N yr−1) of China exhibit as hotspots of soil Nr emissions. In terms of crop-specific emissions, rice, maize and vegetable show as three leading Nr emitters, together accounting for 61% of synthetic N fertilizer-induced Nr emissions from croplands. The global warming effect derived from cropland N2O emissions in China was found to dominate over the local cooling effects of NH3 and NO emissions. Our established regional and crop-specific EFs for gaseous Nr forms provide a new benchmark for constraining the IPCC Tier 1 default EF values. The spatio-temporal insight into soil Nr emission data from N fertilizer application in our estimate is expected to advance our efforts towards more accurate global or regional cropland Nr emission inventories and effective mitigation strategies.

Published

2021

4. Increased soil release of greenhouse gases shrinks terrestrial carbon uptake enhancement under warming

Author

Jianwen Zou, Yiqi Luo, Kai Yu, Shuqing Li, Shuqi Xiao, Jinyang Wang, Zhaoqiang Han, Ruoya Ma, Shuang Wu, Shuwei Liu, Yajing Zheng, and Zhaofu Li

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Nitrous Oxide, Climate change, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Methane, Soil respiration, Greenhouse Gases, Soil, chemistry.chemical_compound, Environmental Chemistry, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, Ecology, Soil organic matter, Nitrous oxide, Carbon Dioxide, Carbon, chemistry, Greenhouse gas, Soil water, Environmental science

Abstract

Warming can accelerate the decomposition of soil organic matter and stimulate the release of soil greenhouse gases (GHGs), but to what extent soil release of methane (CH4 ) and nitrous oxide (N2 O) may contribute to soil C loss for driving climate change under warming remains unresolved. By synthesizing 1,845 measurements from 164 peer-reviewed publications, we show that around 1.5°C (1.16-2.01°C) of experimental warming significantly stimulates soil respiration by 12.9%, N2 O emissions by 35.2%, CH4 emissions by 23.4% from rice paddies, and by 37.5% from natural wetlands. Rising temperature increases CH4 uptake of upland soils by 13.8%. Warming-enhanced emission of soil CH4 and N2 O corresponds to an overall source strength of 1.19, 1.84, and 3.12 Pg CO2 -equivalent/year under 1°C, 1.5°C, and 2°C warming scenarios, respectively, interacting with soil C loss of 1.60 Pg CO2 /year in terms of contribution to climate change. The warming-induced rise in soil CH4 and N2 O emissions (1.84 Pg CO2 -equivalent/year) could reduce mitigation potential of terrestrial net ecosystem production by 8.3% (NEP, 22.25 Pg CO2 /year) under warming. Soil respiration and CH4 release are intensified following the mean warming threshold of 1.5°C scenario, as compared to soil CH4 uptake and N2 O release with a reduced and less positive response, respectively. Soil C loss increases to a larger extent under soil warming than under canopy air warming. Warming-raised emission of soil GHG increases with the intensity of temperature rise but decreases with the extension of experimental duration. This synthesis takes the lead to quantify the ecosystem C and N cycling in response to warming and advances our capacity to predict terrestrial feedback to climate change under projected warming scenarios.

Published

2020

5. A meta-analysis of fertilizer-induced soil NO and combined NO+N2O emissions

Author

Feng Lin, Jianwen Zou, Shuang Wu, Cheng Ji, Yaguo Jin, Yi Sun, Shuqing Li, Shuwei Liu, and Zhaofu Li

Subjects

Global and Planetary Change, Crop residue, Irrigation, Ecology, Ammonium nitrate, chemistry.chemical_element, 04 agricultural and veterinary sciences, 010501 environmental sciences, engineering.material, 01 natural sciences, Nitrogen, Tillage, chemistry.chemical_compound, chemistry, Agronomy, Soil water, 040103 agronomy & agriculture, engineering, 0401 agriculture, forestry, and fisheries, Environmental Chemistry, Environmental science, Nitrification, Fertilizer, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Soils are among the important sources of atmospheric nitric oxide (NO) and nitrous oxide (N2O), acting as a critical role in atmospheric chemistry. Updated data derived from 114 peer-reviewed publications with 520 field measurements were synthesized using meta-analysis procedure to examine the N fertilizer-induced soil NO and the combined with N2O (NO+N2O) emissions across global soils. Besides factors identified in earlier reviews, additional factors responsible for NO fluxes were fertilizer type, soil C/N ratio, crop residue incorporation, tillage, atmospheric carbon dioxide concentration, drought and biomass burning. When averaged across all measurements, soil NO-N fluxes were estimated to be 4.06 kg ha−1 yr−1, with the greatest (9.75 kg ha−1 yr−1) in vegetable croplands and the lowest (0.11 kg ha−1 yr−1) in rice paddies. Soil NO emissions were more enhanced by synthetic N fertilizer (+38%), relative to organic (+20%) or mixed N (+18%) sources. Compared with synthetic N fertilizer alone, synthetic N fertilizer combined with nitrification inhibitors substantially reduced soil NO emissions by 81%. The global mean direct emission factors of N fertilizer for NO (EFNO) and combined NO+N2O (EFc) were estimated to be 1.16% and 2.58%, with 95% confidence intervals of 0.71–1.61% and 1.81–3.35%, respectively. Forests had the greatest EFNO (2.39%). Within the croplands, the EFNO (1.71%) and EFc (4.13%) were the greatest in vegetable cropping fields. Among different chemical N fertilizer varieties, ammonium nitrate had the greatest EFNO (2.93%) and EFc (5.97%). Some options such as organic instead of synthetic N fertilizer, decreasing N fertilizer input rate, nitrification inhibitor, and low irrigation frequency could be adopted to mitigate soil NO emissions. More field measurements over multi-years are highly needed to minimize the estimate uncertainties and mitigate soil NO emissions, particularly in forests and vegetable croplands. This article is protected by copyright. All rights reserved.

Published

2016

6. A meta-analysis of fertilizer-induced soil NO and combined NO+N

Author

Shuwei, Liu, Feng, Lin, Shuang, Wu, Cheng, Ji, Yi, Sun, Yaguo, Jin, Shuqing, Li, Zhaofu, Li, and Jianwen, Zou

Subjects

Crops, Agricultural, Soil, Nitrous Oxide, Forests, Fertilizers, Nitric Oxide

Abstract

Soils are among the important sources of atmospheric nitric oxide (NO) and nitrous oxide (N

Published

2016

7. Changes in fertilizer-induced direct N2O emissions from paddy fields during rice-growing season in China between 1950s and 1990s

Author

Genxing Pan, Qiaohui Liu, Yao Huang, Qirong Shen, Yanmei Qin, Yanyu Lu, Jianwen Zou, and Shuwei Liu

Subjects

Global and Planetary Change, Irrigation, Ecology, business.industry, chemistry.chemical_element, Growing season, Nitrous oxide, engineering.material, Nitrogen, chemistry.chemical_compound, chemistry, Agronomy, Agriculture, Greenhouse gas, engineering, Environmental Chemistry, Environmental science, Paddy field, Fertilizer, business, General Environmental Science

Abstract

Nitrogen fertilizer-induced direct nitrous oxide (N2O) emissions depend on water regimes in paddy fields, such as seasonal continuous flooding (F), flooding‐midseason drainage‐reflooding (F-D-F), and flooding‐midseason drainage‐reflooding‐moist intermittent irrigation but without water logging (F-D-F-M). In order to estimate the changes in direct N2O emission from paddy fields during the rice-growing season in Mainland of China between the 1950s and the 1990s, the country-specific emission factors of N2O-N under different water regimes combined with rice production data were adopted in the present study. Census statistics on rice production showed that water management and nitrogen input regimes have changed in rice paddies since the 1950s. During the 1950s‐ 1970s, about 20‐25% of the rice paddy was continuously waterlogged, and 75‐80% under the water regime of F-D-F. Since the 1980s, about 12‐16%, 77%, and 7‐12% of paddy fields were under the water regimes of F, F-D-F, and F-D-F-M, respectively. Total nitrogen input during the rice-growing season has increased from 87.5kgNha � 1 in the 1950s to 224.6kgNha � 1 in the 1990s. The emission factors of N2O-N were estimated to be 0.02%, 0.42%, and 0.73% for rice paddies under the F, F-D-F, and F-D-F-M water regimes, respectively. Seasonal N2O emissions have increased from 9.6Gg N2O-N each year in the 1950s to 32.3Gg N2O-N in the 1990s, which is accompanied by the increase in rice yield over the period 1950s‐1990s. The uncertainties in N2O estimate were estimated to be 59.8% in the 1950s and 37.5% in the 1990s. In the 1990s, N2O emissions during the ricegrowing season accounted for 8‐11% of the reported annual total of N2O emissions from croplands in China, suggesting that paddy rice development could have contributed to mitigating agricultural N2O emissions in the past decades. However, seasonal N2O emissions would be increased, given that saving-water irrigation and nitrogen inputs are increasingly adopted in rice paddies in China.

Published

2009

8. Enhanced CO2 uptake is marginally offset by altered fluxes of non‐CO2 greenhouse gases in global forests and grasslands under N deposition.

Author

Xiao, Shuqi, Wang, Chao, Yu, Kai, Liu, Genyuan, Wu, Shuang, Wang, Jinyang, Niu, Shuli, Zou, Jianwen, and Liu, Shuwei

Subjects

HETEROTROPHIC respiration, GREENHOUSE gases, GRASSLANDS, ATMOSPHERIC carbon dioxide, SOIL respiration, ATMOSPHERIC nitrogen, PLATEAUS, LAND cover

Abstract

Despite the increasing impact of atmospheric nitrogen (N) deposition on terrestrial greenhouse gas (GHG) budget, through driving both the net atmospheric CO2 exchange and the emission or uptake of non‐CO2 GHGs (CH4 and N2O), few studies have assessed the climatic impact of forests and grasslands under N deposition globally based on different bottom‐up approaches. Here, we quantify the effects of N deposition on biomass C increment, soil organic C (SOC), CH4 and N2O fluxes and, ultimately, the net ecosystem GHG balance of forests and grasslands using a global comprehensive dataset. We showed that N addition significantly increased plant C uptake (net primary production) in forests and grasslands, to a larger extent for the aboveground C (aboveground net primary production), whereas it only caused a small or insignificant enhancement of SOC pool in both upland systems. Nitrogen addition had no significant effect on soil heterotrophic respiration (RH) in both forests and grasslands, while a significant N‐induced increase in soil CO2 fluxes (RS, soil respiration) was observed in grasslands. Nitrogen addition significantly stimulated soil N2O fluxes in forests (76%), to a larger extent in grasslands (87%), but showed a consistent trend to decrease soil uptake of CH4, suggesting a declined sink capacity of forests and grasslands for atmospheric CH4 under N enrichment. Overall, the net GHG balance estimated by the net ecosystem production‐based method (forest, 1.28 Pg CO2‐eq year−1 vs. grassland, 0.58 Pg CO2‐eq year−1) was greater than those estimated using the SOC‐based method (forest, 0.32 Pg CO2‐eq year−1 vs. grassland, 0.18 Pg CO2‐eq year−1) caused by N addition. Our findings revealed that the enhanced soil C sequestration by N addition in global forests and grasslands could be only marginally offset (1.5%–4.8%) by the combined effects of its stimulation of N2O emissions together with the reduced soil uptake of CH4. [ABSTRACT FROM AUTHOR]

Published

2023

9. Global methane and nitrous oxide emissions from inland waters and estuaries.

Author

Zheng, Yajing, Wu, Shuang, Xiao, Shuqi, Yu, Kai, Fang, Xiantao, Xia, Longlong, Wang, Jinyang, Liu, Shuwei, Freeman, Chris, and Zou, Jianwen

Subjects

NITROUS oxide, ESTUARIES, CARBON emissions, METHANE, EBULLITION, OXYGEN in water, CARBON dioxide

Abstract

Inland waters (rivers, reservoirs, lakes, ponds, streams) and estuaries are significant emitters of methane (CH4) and nitrous oxide (N2O) to the atmosphere, while global estimates of these emissions have been hampered due to the lack of a worldwide comprehensive data set of CH4 and N2O flux components. Here, we synthesize 2997 in‐situ flux or concentration measurements of CH4 and N2O from 277 peer‐reviewed publications to estimate global CH4 and N2O emissions from inland waters and estuaries. Inland waters including rivers, reservoirs, lakes, and streams together release 95.18 Tg CH4 year−1 (ebullition plus diffusion) and 1.48 Tg N2O year−1 (diffusion) to the atmosphere, yielding an overall CO2‐equivalent emission total of 3.06 Pg CO2 year−1. The estimate of CH4 and N2O emissions represents roughly 60% of CO2 emissions (5.13 Pg CO2 year−1) from these four inland aquatic systems, among which lakes act as the largest emitter for both CH4 and N2O. Ebullition showed as a dominant flux component of CH4, contributing up to 62%–84% of total CH4 fluxes across all inland waters. Chamber‐derived CH4 emission rates are significantly greater than those determined by diffusion model‐based methods for commonly capturing of both diffusive and ebullitive fluxes. Water dissolved oxygen (DO) showed as a dominant factor among all variables to influence both CH4 (diffusive and ebullitive) and N2O fluxes from inland waters. Our study reveals a major oversight in regional and global CH4 budgets from inland waters, caused by neglecting the dominant role of ebullition pathways in those emissions. The estimated indirect N2O EF5 values suggest that a downward refinement is required in current IPCC default EF5 values for inland waters and estuaries. Our findings further indicate that a comprehensive understanding of the magnitude and patterns of CH4 and N2O emissions from inland waters and estuaries is essential in defining the way of how these aquatic systems will shape our climate. [ABSTRACT FROM AUTHOR]

Published

2022

10. Data‐driven estimates of fertilizer‐induced soil NH3, NO and N2O emissions from croplands in China and their climate change impacts.

Author

Ma, Ruoya, Yu, Kai, Xiao, Shuqi, Liu, Shuwei, Ciais, Philippe, and Zou, Jianwen

Subjects

CLIMATE change, FARMS, SYNTHETIC fertilizers, FERTILIZER application, SOILS, FERTILIZERS

Abstract

Gaseous reactive nitrogen (Nr) emissions from agricultural soils to the atmosphere constitute an integral part of global N cycle, directly or indirectly causing climate change impacts. The extensive use of N fertilizer in crop production will compromise our efforts to reduce agricultural Nr emissions in China. A national inventory of fertilizer N‐induced gaseous Nr emissions from croplands in China remains to be developed to reveal its role in shaping climate change. Here we present a data‐driven estimate of fertilizer N‐induced soil Nr emissions based on regional and crop‐specific emission factors (EFs) compiled from 379 manipulative studies. In China, agricultural soil Nr emissions from the use of synthetic N fertilizer and manure in 2018 are estimated to be 3.81 and 0.73 Tg N yr−1, with a combined contribution of 23%, 20% and 15% to the global agricultural emission total of ammonia (NH3), nitrous oxide (N2O) and nitric oxide (NO), respectively. Over the past three decades, NH3 volatilization from croplands has experienced a shift from a rapid increase to a decline trend, whereas N2O and NO emissions always maintain a strong growth momentum due to a robust and continuous rise of EFs. Regionally, croplands in Central south (1.51 Tg N yr−1) and East (0.99 Tg N yr−1) of China exhibit as hotspots of soil Nr emissions. In terms of crop‐specific emissions, rice, maize and vegetable show as three leading Nr emitters, together accounting for 61% of synthetic N fertilizer‐induced Nr emissions from croplands. The global warming effect derived from cropland N2O emissions in China was found to dominate over the local cooling effects of NH3 and NO emissions. Our established regional and crop‐specific EFs for gaseous Nr forms provide a new benchmark for constraining the IPCC Tier 1 default EF values. The spatio‐temporal insight into soil Nr emission data from N fertilizer application in our estimate is expected to advance our efforts towards more accurate global or regional cropland Nr emission inventories and effective mitigation strategies. [ABSTRACT FROM AUTHOR]

Published

2022

11. Global soil‐derived ammonia emissions from agricultural nitrogen fertilizer application: A refinement based on regional and crop‐specific emission factors.

Author

Ma, Ruoya, Zou, Jianwen, Han, Zhaoqiang, Yu, Kai, Wu, Shuang, Li, Zhaofu, Liu, Shuwei, Niu, Shuli, Horwath, William R., and Zhu‐Barker, Xia

Subjects

NITROGEN fertilizers, SYNTHETIC fertilizers, FERTILIZERS, SOIL air, AMMONIA, FERTILIZER application

Abstract

Ammonia (NH3) emissions from fertilized soils to the atmosphere and the subsequent deposition to land surface exert adverse effects on biogeochemical nitrogen (N) cycling. The region‐ and crop‐specific emission factors (EFs) of N fertilizer for NH3 are poorly developed and therefore the global estimate of soil NH3 emissions from agricultural N fertilizer application is constrained. Here we quantified the region‐ and crop‐specific NH3 EFs of N fertilizer by compiling data from 324 worldwide manipulative studies and focused to map the global soil NH3 emissions from agricultural N fertilizer application. Globally, the NH3 EFs averaged 12.56% and 14.12% for synthetic N fertilizer and manure, respectively. Regionally, south‐eastern Asia had the highest NH3 EFs of synthetic N fertilizer (19.48%) and Europe had the lowest (6%), which might have been associated with the regional discrepancy in the form and rate of N fertilizer use and management practices in agricultural production. Global agricultural NH3 emissions from the use of synthetic N fertilizer and manure in 2014 were estimated to be 12.32 and 3.79 Tg N/year, respectively. China (4.20 Tg N/year) followed by India (2.37 Tg N/year) and America (1.05 Tg N/year) together contributed to over 60% of the total global agricultural NH3 emissions from the use of synthetic N fertilizer. For crop‐specific emissions, the NH3 EFs averaged 11.13%–13.95% for the three main staple crops (i.e., maize, wheat, and rice), together accounting for 72% of synthetic N fertilizer‐induced NH3 emissions from croplands in the world and 70% in China. The region‐ and crop‐specific NH3 EFs of N fertilizer established in this study offer references to update the default EF in the IPCC Tier 1 guideline. This work also provides an insight into the spatial variation of soil‐derived NH3 emissions from the use of synthetic N fertilizer in agriculture at the global and regional scales. [ABSTRACT FROM AUTHOR]

Published

2021

12. Increased soil release of greenhouse gases shrinks terrestrial carbon uptake enhancement under warming.

Author

Liu, Shuwei, Zheng, Yajing, Ma, Ruoya, Yu, Kai, Han, Zhaoqiang, Xiao, Shuqi, Li, Zhaofu, Wu, Shuang, Li, Shuqing, Wang, Jinyang, Luo, Yiqi, and Zou, Jianwen

Subjects

GREENHOUSE gases, CLIMATE feedbacks, HUMUS, POTTING soils, TUNDRAS, SOIL respiration

Abstract

Warming can accelerate the decomposition of soil organic matter and stimulate the release of soil greenhouse gases (GHGs), but to what extent soil release of methane (CH4) and nitrous oxide (N2O) may contribute to soil C loss for driving climate change under warming remains unresolved. By synthesizing 1,845 measurements from 164 peer‐reviewed publications, we show that around 1.5°C (1.16–2.01°C) of experimental warming significantly stimulates soil respiration by 12.9%, N2O emissions by 35.2%, CH4 emissions by 23.4% from rice paddies, and by 37.5% from natural wetlands. Rising temperature increases CH4 uptake of upland soils by 13.8%. Warming‐enhanced emission of soil CH4 and N2O corresponds to an overall source strength of 1.19, 1.84, and 3.12 Pg CO2‐equivalent/year under 1°C, 1.5°C, and 2°C warming scenarios, respectively, interacting with soil C loss of 1.60 Pg CO2/year in terms of contribution to climate change. The warming‐induced rise in soil CH4 and N2O emissions (1.84 Pg CO2‐equivalent/year) could reduce mitigation potential of terrestrial net ecosystem production by 8.3% (NEP, 22.25 Pg CO2/year) under warming. Soil respiration and CH4 release are intensified following the mean warming threshold of 1.5°C scenario, as compared to soil CH4 uptake and N2O release with a reduced and less positive response, respectively. Soil C loss increases to a larger extent under soil warming than under canopy air warming. Warming‐raised emission of soil GHG increases with the intensity of temperature rise but decreases with the extension of experimental duration. This synthesis takes the lead to quantify the ecosystem C and N cycling in response to warming and advances our capacity to predict terrestrial feedback to climate change under projected warming scenarios. [ABSTRACT FROM AUTHOR]

Published

2020