Carbon footprint of farming practices in farmland ecosystems on the North and Northeast China plains

Yuewen Huo; Guohua Mi; Mengyang Zhu; Shuang Chen; Jing Li; Zhanhong Hao; Dongyu Cai; Fusuo Zhang

doi:10.1016/j.jenvman.2024.120378

Carbon footprint of farming practices in farmland ecosystems on the North and Northeast China plains

J Environ Manage. 2024 Mar:354:120378. doi: 10.1016/j.jenvman.2024.120378. Epub 2024 Feb 13.

Authors

Yuewen Huo¹, Guohua Mi¹, Mengyang Zhu¹, Shuang Chen¹, Jing Li¹, Zhanhong Hao¹, Dongyu Cai², Fusuo Zhang³

Affiliations

¹ National Academy of Agriculture Green Development, College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, China.
² National Academy of Agriculture Green Development, College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, China. Electronic address: cdongyu@126.com.
³ National Academy of Agriculture Green Development, College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, China. Electronic address: zhangfs@cau.edu.cn.

PMID: 38350277
DOI: 10.1016/j.jenvman.2024.120378

Abstract

Fast development of farming practices in China is projected to result in additional carbon emissions and thus affect farmland ecosystems' environmental performance. Based on 454 farm surveys on the North and Northeast China Plain, the carbon footprint (CF) of two farmland ecosystems (irrigated system for wheat and maize on the North China Plain and rainfed system for maize on the Northeast Plain) were assessed and emission reduction pathways explored by quantifying greenhouse gas emissions of agricultural inputs and farm practices during the entire crop growing seasons with an agricultural footprint model. The results demonstrated that the GHG emissions from wheat and maize rotation in the irrigated system were 7.63 t CO₂ eq ha^-1 and 3.17 t CO₂ eq ha^-1 for single season maize in the rainfed system. While energy consumption accounted for 12.5%-21.3% of the carbon footprint in both systems, the group assessment found that the largest difference in GHG emissions between the high and low emission groups came from mechanical energy consumption. Approximately 50.6% and 39.2% of the mechanical carbon footprint of wheat and maize, respectively, were caused by irrigation practices in the irrigated system. Regarding the rainfed system, where 46.6% of mechanical carbon emissions were generated by maize tillage operations. In addition, scenario analysis indicated that the mechanical carbon footprint could be reduced to 56 kg CO₂ eq t^-1 for NCP-wheat and 26 kg CO₂ eq t^-1 for NCP-maize, respectively, by optimizing yields and irrigation practices in irrigated systems and that the mechanical carbon footprint of NEP-maize could be reduced to 25 kg CO₂ eq t^-1 by optimizing yields and tillage practices in rainfed systems. Therefore, improvement in mechanization in irrigation and tillage practices can contribute to reduce GHG emissions in China. Water-saving irrigation technology is recommended in irrigated area and conservation tillage is recommended in rainfed agricultural area to reduce carbon footprints.

Keywords: Carbon footprint; Farming practices; Farmland ecosystems; Greenhouse gas mitigation; Mechanized grain production.

MeSH terms

Agriculture / methods
Carbon / analysis
Carbon Dioxide*
Carbon Footprint*
China
Ecosystem
Farms
Soil
Triticum
Zea mays

Substances

Carbon Dioxide
Carbon
Soil