A new University of California San Diego study uncovers a hidden driver of global crop vulnerability: the origin of rainfall itself. Published in Nature Sustainability, the research traces atmospheric moisture back to its source - whether it evaporated from the ocean or from land surfaces such as soil, lakes and forests. When the sun heats these surfaces, water turns into vapor, rises into the atmosphere, and later falls again as rain.
Ocean-sourced moisture travels long distances on global winds, often through large-scale weather systems such as atmospheric rivers, monsoons, and tropical storms. In contrast, land-sourced moisture - often called recycled rainfall - comes from water that evaporates nearby soils and vegetation, feeding local storms. The study finds that this balance between oceanic and terrestrial (land) sources strongly influences a region's drought risk and crop productivity.
"Our work reframes drought risk - it's not just about how much it rains, but where that rain comes from," said Yan Jiang, the study's lead author and postdoctoral scholar at UC San Diego with a joint appointment at the School of Global Policy and Strategy and Scripps Institution of Oceanography. "Understanding the origin of rainfall and whether it comes from oceanic or land sources, gives policymakers and farmers a new tool to predict and mitigate drought stress before it happens."
This insight provides a new way for farmers and policymakers to identify which regions are most at risk - and to plan accordingly.
"For farmers in areas that rely heavily on land-originating moisture - like parts of the Midwest or eastern Africa - local water availability becomes the deciding factor for crop success," Jiang explained. "Changes in soil moisture or deforestation can have immediate, cascading impacts on yields."
In the Midwest, Jiang notes, droughts have become more frequent and intense in recent years - even in one of the world's most productive and technologically advanced farming regions.
"Our findings suggest that the Midwest's high reliance on land-sourced moisture, from surrounding soil and vegetation, could amplify droughts through what we call 'rainfall feedback loops,'" Jiang said. "When the land dries out, it reduces evaporation, which in turn reduces future rainfall - creating a self-reinforcing drought cycle."
Because this region is also a major supplier to global grain markets, disruptions there have ripple effects far beyond U.S. borders. Jiang suggests that Midwestern producers may need to pay closer attention to soil moisture management, irrigation efficiency and timing of planting to avoid compounding drought stress.
In contrast, East Africa faces a more precarious but still reversible situation. Rapid cropland expansion and loss of surrounding rainforests threaten to undermine the very moisture sources that sustain rainfall in the region.
"This creates a dangerous conflict," Jiang said. "Farmers are clearing forests to grow more crops, but those forests help generate the rainfall that the crops depend on. If that moisture source disappears, local food security will be at greater risk."
However, Jiang sees opportunity as well as risk: "Eastern Africa is on the front line of change, but there is still time to act. Smarter land management - like conserving forests and restoring vegetation - can protect rainfall and sustain agricultural growth."
"Upland forests are like natural rainmakers," Jiang said. "Protecting these ecosystems isn't just about biodiversity - it's about sustaining agriculture."
The study's novel satellite-based mapping technique could help governments and farmers identify where to invest in irrigation infrastructure, soil water storage and forest conservation to maintain reliable rainfall.
Research Report:Crop water origins and hydroclimate vulnerability of global croplands
Related Links
University of California - San Diego
Climate Science News - Modeling, Mitigation Adaptation
| Subscribe Free To Our Daily Newsletters |
| Subscribe Free To Our Daily Newsletters |
