Responses of Soil N2O Emission and CH4 Uptake to N Input in Chinese Forests across Climatic Zones: A Meta-Study

Zhang, Bei; Huang, Yuanyuan; Qu, Zhi; Zhu, Tongbin; Yu, Longfei

doi:10.3390/atmos13071145

Cited by 2 publications

(2 citation statements)

References 82 publications

(104 reference statements)

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“…S8 ). Previous studies based on a meta‐analysis [ 44 ], a conceptual model [ 29 ], and an ensemble of terrestrial biosphere model showed that atmospheric N deposition enhances natural soil N 2 O emissions [ 45 ], which was consistent with our results. Apart from the effect of atmospheric N deposition, climate change leaded to an increase of 1.6 Gg N 2 O yr −1 for soil N 2 O emissions ( Fig.…”

Section: Discussionsupporting

confidence: 92%

Four decades of full-scale nitrous oxide emission inventory in China

Liang,

Zhou,

Ren

et al. 2023

National Science Review

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China is among the top nitrous oxide (N2O)-emitting countries, but existing national inventories do not provide full-scale emissions including both natural and anthropogenic sources. We conducted a four-decade (1980–2020) of comprehensive quantification of Chinese N2O inventory using empirical emission factor method for anthropogenic sources and two up-to-date process-based models for natural sources. Total N2O emissions peaked at 2287.4 (1774.8–2799.9) Gg N2O yr−1 in 2018, and agriculture-developed regions, like the East, Northeast, and Central, were the top N2O-emitting regions. Agricultural N2O emissions have started to decrease after 2016 due to the decline of nitrogen fertilization applications, while, industrial and energetic sources have been dramatically increasing after 2005. N2O emissions from agriculture, industry, energy, and waste represented 49.3%, 26.4%, 17.5%, and 6.7% of the anthropogenic emissions in 2020, respectively, which revealed that it is imperative to prioritize N2O emission mitigation in agriculture, industry, and energy. Natural N2O sources, dominated by forests, have been steadily growing from 317.3 (290.3–344.1) Gg N2O yr−1 in 1980 to 376.2 (335.5–407.2) Gg N2O yr−1 in 2020. Our study produces a Full-scale Annual N2O dataset in China (FAN2020), providing emergent counting to refine the current national N2O inventories.

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Section: Discussionsupporting

confidence: 92%

Four decades of full-scale nitrous oxide emission inventory in China

Liang,

Zhou,

Ren

et al. 2023

National Science Review

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“…In this study, N addition significantly positively affected soil N 2 O emissions in three points, with similar phenomena observed in irrigated maize in a Mediterranean agroecosystem [27]. N addition tends to promote N 2 O emissions, and it has been found that among the various factors affecting soil N 2 O emissions, the amount of N application is the most decisive [28,29]. The nitrification process gradually depletes the soil of energy materials and easily decomposable organic N, so the gas emissions gradually stabilize in the later stages [30].…”

Section: Discussionsupporting

confidence: 80%

The Responses of N2O, CO2 Emissions, and Bacterial Communities to Nitrogen Addition in Saline–Alkaline Wetlands of Northeast China

Su,

Liang,

et al. 2023

Atmosphere

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The Zhalong Wetland is impacted by elevated atmospheric nitrogen (N) deposition and N inputs from agricultural fertilization, which in turn affect greenhouse gas (GHG) emissions. It is unclear how N addition affects nitrous oxide (N2O) and carbon dioxide (CO2) emissions in this wetland. Therefore, we conducted a short-term experiment, collecting soil samples from three representative points with different water levels, and five N addition levels (N0 = 0 mg N kg−1, N10 = 10 mg N kg−1, N30 = 30 mg N kg−1, N50 = 50 mg N kg−1, N100 = 100 mg N kg−1) were used to simulate N input. Overall, N2O emissions were significantly increased by N addition. Differently, N addition had a significant suppressive effect on CO2 emissions in high-flooded soils, whereas the highest CO2 emissions were regarded under the N30 treatment in middle-flooded and dry soils. Through Pearson’s correlation analysis, we found a significant positive correlation between N2O emissions and ammonium (NH4+), and CO2 emission was significantly positively correlated with pH and total organic carbon (TOC). Meanwhile, the bacterial community of the soil was analyzed via high-throughput sequencing. The results revealed that N addition was not significantly affecting soil bacterial community structure, while the three points were significantly different. Among them, the relative abundance of the dominant genera of Trichoderma and Pseudomonas were significantly enhanced after N addition. Furthermore, the bacterial communities were found to be significantly correlated with soil pH, TOC, NH4+, and nitrate contents, which affected N2O and CO2 emissions.

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Responses of Soil N2O Emission and CH4 Uptake to N Input in Chinese Forests across Climatic Zones: A Meta-Study

Cited by 2 publications

References 82 publications

Four decades of full-scale nitrous oxide emission inventory in China

Four decades of full-scale nitrous oxide emission inventory in China

The Responses of N2O, CO2 Emissions, and Bacterial Communities to Nitrogen Addition in Saline–Alkaline Wetlands of Northeast China

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