Spatially Optimized Nutrient Management as a Climate-Resilient Strategy to Reduce Nitrogen Runoff from Global Croplands.

Nitrogen fertilizer, as an indispensable input in crop production, has played a crucial role in enhancing crop yields. However, the associated cropland nitrogen runoff has significantly intensified surface water eutrophication, posing serious threats to aquatic ecosystems globally. Accurate estimation of cropland nitrogen runoff is essential for designing effective mitigation strategies, yet research in this area remains constrained by limited data availability. To address this gap, we developed a machine learning model based on a globally compiled data set of field observations. Using a global spatial interpolation approach driven by the similarity of environmental and management variables, we generated crop-specific, high-resolution global maps of nitrogen runoff emission factors. Our results showed that synthetic nitrogen fertilizer application in rice, wheat, and maize fields generated approximately 2.33 Tg N yr