College of Environmental and Resource Sciences, Zhejiang University, Hangzhou, China.
National Engineering and Technology Center for Information Agriculture, Engineering Research Center of Smart Agriculture, Ministry of Education, Key Laboratory for Crop System Analysis and Decision Making, Ministry of Agriculture, Jiangsu Key Laboratory for Information Agriculture, Jiangsu Collaborative Innovation Center for Modern Crop Production, Nanjing Agricultural University, Nanjing, China.
Nat Food. 2024 Jan;5(1):59-71. doi: 10.1038/s43016-023-00891-x. Epub 2024 Jan 2.
Co-optimization of multiple management practices may facilitate climate-smart agriculture, but is challenged by complex climate-crop-soil management interconnections across space and over time. Here we develop a hybrid approach combining agricultural system modelling, machine learning and life cycle assessment to spatiotemporally co-optimize fertilizer application, irrigation and residue management to achieve yield potential of wheat and maize and minimize greenhouse gas emissions in the North China Plain. We found that the optimal fertilizer application rate and irrigation for the historical period (1995-2014) are lower than local farmers' practices as well as trial-derived recommendations. With the optimized practices, the projected annual requirement of fertilizer, irrigation water and residue inputs across the North China Plain in the period 2051-2070 is reduced by 16% (14-21%) (mean with 95% confidence interval), 19% (7-32%) and 20% (16-26%), respectively, compared with the current supposed optimal management in the historical reference period, with substantial greenhouse gas emission reductions. We demonstrate the potential of spatiotemporal co-optimization of multiple management practices and present digital mapping of management practices as a benchmark for site-specific management across the region.
多种管理措施的协同优化可能有助于实现气候智能型农业,但受到跨时空的气候-作物-土壤管理相互关系的复杂性的挑战。在这里,我们开发了一种混合方法,结合农业系统建模、机器学习和生命周期评估,对肥料施用、灌溉和残留物管理进行时空协同优化,以实现小麦和玉米的产量潜力,并最大限度地减少华北平原的温室气体排放。我们发现,历史时期(1995-2014 年)的最优肥料施用量和灌溉量低于当地农民的做法以及试验得出的建议。通过优化措施,预计 2051-2070 年期间华北平原的肥料、灌溉用水和残留物投入的年需求量将分别减少 16%(14-21%)(95%置信区间的平均值)、19%(7-32%)和 20%(16-26%),与历史参考期当前假定的最优管理相比,温室气体排放量大幅减少。我们展示了多种管理措施时空协同优化的潜力,并提出了管理措施的数字地图,作为该地区特定地点管理的基准。
