“双碳”目标下新疆主要农作物生产碳足迹

doi:10.13287/j.1001-9332.202503.028

摘要/Abstract

摘要： 新疆是我国棉花的主产区和粮食作物的重要生产基地,如今正面临着保障国家粮食安全和实现低碳农业发展的双重压力。全面核算该地区主要农作物生产碳足迹,可从碳减排的视角为新疆主要农作物种植结构调整和生产体系全过程环境管理提供决策依据。本研究基于2005—2021年新疆小麦、玉米和棉花的种植面积、产量和农资生产投入量等数据,采用生命周期评价法核算该区域上述3大主要农作物的生产碳足迹,并采用灰色关联度分析其影响因素。结果表明: 2005—2021年间,新疆小麦、玉米的种植面积主要随棉花种植面积的变动而变动。小麦、玉米和棉花的年均单位面积碳足迹分别为2.21、2.67、3.61 t CE·hm^-2;年均单位产量碳足迹分别为0.41、0.35、1.91 t CE·t^-1。在碳效率上,3种作物的碳生态效率表现为:小麦(10.99 t CE·t CE^-1)>玉米(9.68 t CE·t CE^-1)>棉花(2.96 t CE·t CE^-1);碳生产效率表现为:玉米(2.88 t·t CE^-1)>小麦(2.48 t·t CE^-1)>棉花(0.53 t·t CE^-1);碳经济效率表现为:棉花(7148.74×10³ yuan·t CE^-1)>玉米(6094.32×10³ yuan·t CE^-1)>小麦(5904.23×10³ yuan·t CE^-1)。在碳投入结构上,农田N₂O排放和化肥投入是3种作物生产碳足迹的主要来源;机械总动力、作物种植面积、有效灌溉面积、农膜用量、复合肥和氮肥投入的变化是作物碳足迹年际变化的主要驱动因素。由2022、2023年新疆小麦、玉米和棉花的生产碳足迹分析可知,未来新疆需要适度调整3大主要农作物的种植结构,并通过科技进步提高化肥利用效率、农膜利用率、灌溉和机械作业效率,在深入实施国家粮食安全战略的同时实现农作物的低碳生产。

关键词: 碳足迹, 生命周期评价, 碳效率, 灰色关联度分析

Abstract: As the main cotton-producing area and an important production base of food in China, Xinjiang is facing the dual pressures of ensuring national food security and achieving low-carbon agriculture. A comprehensive accounting of carbon footprint of major crops can contribute to decision-making in agricultural structure adjustment and the environmental management in Xinjiang from the perspective of carbon emission reduction. Based on data of the planting area, yield, and agricultural input of wheat, maize, and cotton in Xinjiang from 2005 to 2021, we used the life cycle assessment method to calculate the production carbon footprint of the aforementioned three major crops and used the grey relational analysis to analyze their influencing factors. Results showed that during 2005-2021, the planting areas of wheat and maize varied with the planting area of cotton. The average annual carbon footprint per unit area of wheat, maize, and cotton were 2.21, 2.67, and 3.61 t CE·hm^-2, and the average annual carbon footprint per unit yield were 0.41, 0.35, and 1.91 t CE·t^-1 respectively. The carbon ecological efficiency of the three crops was in an order of wheat (10.99 t CE·t CE^-1) > maize (9.68 t CE·t CE^-1) > cotton (2.96 t CE·t CE^-1), the carbon production efficiency was maize (2.88 t·t CE^-1) > wheat (2.48 t·t CE^-1) > cotton (0.53 t·t CE^-1), and the carbon economic efficiency was cotton (7148.74×10³ yuan·t CE^-1) > maize (6094.32×10³ yuan·t CE^-1) > wheat (5904.23×10³ yuan·t CE^-1). As for carbon input structure, farmland N₂O emission and chemical fertilizer input were the main sources of the production carbon footprint. Total mechanical power, crop planting area, effective irrigation area, agricultural film usage, compound fertilizer and nitrogen fertilizer input were the main driving factors. Based on our analysis of carbon footprint of wheat, maize, and cotton in Xinjiang in 2022 and 2023, we found that this area need to moderately adjust the planting structure in the future. At the same time, it should develop science and technology to improve the utilization efficiencies of chemical fertilizers, agricultural films, irrigation and mechanical operations to achieve the low-carbon production of crops while ensuring the national food security strategy.

Key words: carbon footprint, life cycle assessment, carbon efficiency, grey relation analysis

杨璐, 乐凯迪, 张立杰. “双碳”目标下新疆主要农作物生产碳足迹[J]. 应用生态学报, 2025, 36(4): 1147-1158.

YANG Lu, YUE Kaidi, ZHANG Lijie. Carbon footprint of major crop production under the goal of ‘double carbon' in Xinjiang, China[J]. Chinese Journal of Applied Ecology, 2025, 36(4): 1147-1158.

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