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

• Published in: Carbon balance and management Vol. 14; no. 1; pp. 20 - 10
• Main Authors: Chai, Rushan, Ye, Xinxin, Ma, Chao, Wang, Qingyun, Tu, Renfeng, Zhang, Ligan, Gao, Hongjian
• Format: Journal Article
• Language: English
• Published: Cham Springer International Publishing 30.12.2019; Springer Nature B.V; BMC
• Subjects: Agricultural land; agricultural soils; Application; application rate; Carbon dioxide; Cereal crops; China; Corn; Crop production; cropland; crops; Cultivation; Earth and Environmental Science; Ecosystems; Emission inventories; Emissions; Environment; Environmental Management; Fertilization; fertilizer application; fertilizer industry; Fertilizers; Forestry; Grain cultivation; Greenhouse effect; Greenhouse gas emissions; Greenhouse gases; highlands; inventories; Maize; Manufacture; manufacturing; Nitrogen; nitrogen fertilizers; Nitrous oxide; Synthetic N fertilizers; Wheat; China; Maize; Manufacture; Greenhouse gas emissions; Wheat; Application; Synthetic N fertilizers
• ISSN: 1750-0680; 1750-0680
• DOI: 10.1186/s13021-019-0133-9

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.