Weakened growth of cropland‐N<sub>2</sub>O emissions in China associated with nationwide policy interventions

Shang, Ziyin; Zhou, Feng; Smith, Pete; Saikawa, Eri; Ciais, Philippe; Chang, Jinfeng; Tian, Hanqin; Grosso, Stephen J. Del; Ito, Akihiko; Chen, Minpeng; Wang, Qihui; Bo, Yan; Cui, Xiaoqing; Castaldi, Simona; Juszczak, Radosław; Kasimir, Åsa; Magliulo, Vincenzo; Medinets, Sergiy; Медінець, В. І.; Rees, Robert M.; Wohlfahrt, Georg; Sabbatini, Simone

doi:10.1111/gcb.14741

Cited by 62 publications

(48 citation statements)

References 63 publications

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“…Various models may be used to account for scale or leakage effects such as indirect land-use changes (Qin et al, 2016). The methods currently available include datadriven approaches based on worldwide measurement networks (Shang et al, 2019), statistical or empirical flux-upscaling models (Shang et al, 2019;Wang et al, 2019), process-based models and, lastly, integrated assessment models (IAM;Zomer et al, 2016).…”

Section: Discussion and Outlookmentioning

confidence: 99%

“…Various models may be used to account for scale or leakage effects such as indirect land‐use changes (Qin et al, 2016). The methods currently available include data‐driven approaches based on worldwide measurement networks (Shang et al, 2019), statistical or empirical flux‐upscaling models (Shang et al., 2019; Wang et al., 2019), process‐based models and, lastly, integrated assessment models (IAM; Zomer et al., 2016). Process‐based models include a representation of N cycling processes, which are an essential tool in assessing and predicting the terrestrial N cycle and N 2 O fluxes in response to multi‐factor global changes.…”

Section: Discussion and Outlookmentioning

confidence: 99%

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Can N₂O emissions offset the benefits from soil organic carbon storage?

Guenet

Gabrielle

Chenu

et al. 2020

Global Change Biology

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To respect the Paris agreement targeting a limitation of global warming below 2°C by 2100, and possibly below 1.5°C, drastic reductions of greenhouse gas emissions are mandatory but not sufficient. Large‐scale deployment of other climate mitigation strategies is also necessary. Among these, increasing soil organic carbon (SOC) stocks is an important lever because carbon in soils can be stored for long periods and land management options to achieve this already exist and have been widely tested. However, agricultural soils are also an important source of nitrous oxide (N2O), a powerful greenhouse gas, and increasing SOC may influence N2O emissions, likely causing an increase in many cases, thus tending to offset the climate change benefit from increased SOC storage. Here we review the main agricultural management options for increasing SOC stocks. We evaluate the amount of SOC that can be stored as well as resulting changes in N2O emissions to better estimate the climate benefits of these management options. Based on quantitative data obtained from published meta‐analyses and from our current level of understanding, we conclude that the climate mitigation induced by increased SOC storage is generally overestimated if associated N2O emissions are not considered but, with the exception of reduced tillage, is never fully offset. Some options (e.g. biochar or non‐pyrogenic C amendment application) may even decrease N2O emissions.

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Section: Discussion and Outlookmentioning

confidence: 99%

Section: Discussion and Outlookmentioning

confidence: 99%

Can N₂O emissions offset the benefits from soil organic carbon storage?

Guenet

Gabrielle

Chenu

et al. 2020

Global Change Biology

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253

133

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“…N fertilizer-induced direct N 2 O emissions from agricultural fields are critically affected by many factors, including N application rate, climate variables, crop types and soil characteristics [21,[23][24][25][26]. Several models have been developed and used to estimate N fertilizerinduced N 2 O emissions from the soil [25,27,28]. Due to limited availability of enough relevant information, the determination of direct N 2 O emissions from synthetic N fertilization for wheat and maize in China in the current work was done using the IPCC emission factor method combined with region-and crop-specific direct N 2 O emission factors.…”

Section: Discussionmentioning

confidence: 99%

“…China is now on the right track to implement improved N management techniques in croplands, which would help to identify options for lowering GHG emissions from agricultural production. In recent years, N 2 O emissions from Chinese croplands have grown slowly, owing to nationwide policy interventions and prevalence of technological adoptions [28,42,43]. Moreover, technological innovation in China's N fertilizer industry could make a significant contribution to synthetic N manufacture-related GHG emissions reduction [10].…”

Section: Discussionmentioning

confidence: 99%

Greenhouse gas emissions from synthetic nitrogen manufacture and fertilization for main upland crops in China

Chai

Chao

et al. 2019

Carbon Balance Manage

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Background: A significant source of greenhouse gas (GHG) emissions comes from the manufacture of synthetic nitrogen (N) fertilizers consumed in crop production processes. And the application of synthetic N fertilizers is recognized as the most important factor contributing to direct N 2 O emissions from agricultural soils. Based on statistical data and relevant literature, the GHG emissions associated with synthetic N manufacture and fertilization for wheat and maize in different provinces and agricultural regions of China were quantitatively evaluated in the present study. Results:During the 2015-2017 period, the average application rates of synthetic N for wheat and maize in upland fields of China were 222 and 197 kg ha −1 , respectively. The total consumption of synthetic N on wheat and maize was 12.63 Mt year −1 . At the national scale, the GHG emissions associated with the manufacture of synthetic N fertilizers were estimated to be 41.44 and 59.71 Mt CO 2 -eq year −1 for wheat and maize in China, respectively. And the direct N 2 O emissions derived from synthetic N fertilization were estimated to be 35.82 and 69.44 Gg N 2 O year −1 for wheat and maize, respectively. In the main wheat-cultivating regions of China, area-scaled GHG emissions were higher for Inner Mongolia, Jiangsu and Xinjiang provinces. And for maize, Gansu, Xinjiang, Yunnan, Shannxi and Jiangsu provinces had higher area-scaled GHG emissions. Higher yield-scaled GHG emissions for wheat and maize mainly occured in Yunnan and Gansu provinces. Conclusions:The manufacture and application of synthetic N fertilizers for wheat and maize in Chinese croplands is an important source of agricultural GHG emissions. The current study could provide a scientific basis for establishing an inventory of upland GHG emissions in China and developing appropriate mitigation strategies.

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“…A recent global assessment using ensemble of terrestrial biosphere models also found that global N fertilizer application contributes 2.0 ± 0.8 Tg N 2 O-N yr -1 during 2007-2016, manure application contributes 0.6 ± 0.4 Tg N 2 O-N yr -1 , and N deposition contributes 26% of global soil N 2 O emission (Tianet al 2019). Furthermore, the deceases in cropland-N 2 O emissions after 2003 are mainly ascribed to the reduction in usage of N fertilizer in China (Shang et al 2019). Therefore, we hypothesized that soil N contents might play an important role on regulating soil N 2 O emissions at the global scale.…”

Section: Introductionmentioning

confidence: 99%

Soil nitrogen substrates determine global N2O emission more than climate and other soil properties

Zeng

Tian

et al. 2020

Preprint

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Accurate estimation of N 2 O emission is one of the primary objectives to project the warming potential. However, the global patterns and main controlling factors of soil N 2 O emission remain elusive. We compiled a dataset with 6016 field observations from 219 articles and found that the averaged soil N 2 O emission rate was 1111.8 ± 26.59 μg N m-2 day-1. Soil N 2 O emission rates were significantly influenced by climatic factors (i.e. mean annual temperature), soil physical and chemical properties (e.g. pH, nitrate, ammonium, and total nitrogen), and microbial traits (microbial biomass nitrogen) at a global scale. The combined direct effects of soil nitrate, ammonium, and total nitrogen (combined standard coefficient = 0.45) accounted for the most variance of global soil N 2 O emissions (total standard coefficient = 0.84). This study highlights the critical roles of soil nitrogen substrates on N 2 O emission, which will be helpful to optimize the process-models on soil N 2 O emissions.

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Weakened growth of cropland‐N₂O emissions in China associated with nationwide policy interventions

Cited by 62 publications

References 63 publications

Can N₂O emissions offset the benefits from soil organic carbon storage?

Can N₂O emissions offset the benefits from soil organic carbon storage?

Greenhouse gas emissions from synthetic nitrogen manufacture and fertilization for main upland crops in China

Soil nitrogen substrates determine global N2O emission more than climate and other soil properties

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Weakened growth of cropland‐N2O emissions in China associated with nationwide policy interventions

Cited by 62 publications

References 63 publications

Can N2O emissions offset the benefits from soil organic carbon storage?

Can N2O emissions offset the benefits from soil organic carbon storage?

Greenhouse gas emissions from synthetic nitrogen manufacture and fertilization for main upland crops in China

Soil nitrogen substrates determine global N2O emission more than climate and other soil properties

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Product

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Weakened growth of cropland‐N₂O emissions in China associated with nationwide policy interventions

Can N₂O emissions offset the benefits from soil organic carbon storage?

Can N₂O emissions offset the benefits from soil organic carbon storage?