Holistic food system innovation strategies can close up to 80% of China’s domestic protein gaps while reducing global environmental impacts

IF 23.6 Q1 FOOD SCIENCE & TECHNOLOGY

Nature food Pub Date : 2024-07-09 DOI:10.1038/s43016-024-01011-z

Hao Zhao, Xiangwen Fan, Zhaohai Bai, Lin Ma, Chao Wang, Petr Havlík, Zhenling Cui, Juraj Balkovic, Mario Herrero, Zhou Shi, Jinfeng Chang

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Abstract

China’s imports of livestock feed, particularly protein-rich feeds, pose challenges to global environmental sustainability. Achieving protein self-sufficiency for food and feed in China without exceeding environmental boundaries requires integrated measures and optimization of China’s food system. Here we propose holistic food system innovation strategies consisting of three components—technological innovation, integrated spatial planning and demand-side options—to reduce protein import dependency and promote global environmental sustainability. We find that food system innovations can close almost 80% of China’s future protein gaps while reducing 57–85% of agricultural import-embodied environmental impacts. Deploying these innovations would also reduce greenhouse gas emissions (22–27%) and people’s harmful exposure to ammonia (73–81%) compared with the baseline scenario in 2050. Technological innovations play a key role in closing protein gaps, while integrated crop–livestock spatial planning is imperative for achieving environmental and health targets. China’s feed imports have a considerable environmental impact globally. This modelling study quantifies China’s potential protein self-sufficiency by simulating farming spatial relocation according to irrigation water and nitrogen surplus, as well as technological innovations and demand-side measures.

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整体粮食系统创新战略可弥补中国国内高达 80% 的蛋白质缺口，同时减少对全球环境的影响

中国进口的牲畜饲料，尤其是富含蛋白质的饲料，对全球环境可持续性构成了挑战。要实现中国粮食和饲料中蛋白质的自给自足，同时不超越环境极限，需要采取综合措施并优化中国的粮食系统。在此，我们提出了由技术创新、综合空间规划和需求方选择三部分组成的整体粮食系统创新战略，以减少蛋白质进口依赖，促进全球环境可持续性。我们发现，粮食系统创新可以弥补中国未来近 80% 的蛋白质缺口，同时减少 57-85% 的农业进口所体现的环境影响。与 2050 年的基准情景相比，采用这些创新措施还将减少温室气体排放（22-27%）和人们对氨的有害接触（73-81%）。技术创新在缩小蛋白质差距方面发挥着关键作用，而作物-牲畜综合空间规划则是实现环境和健康目标的当务之急。

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来源期刊

Nature food

CiteScore

28.50

自引率

0.00%

发文量