Revolutionizing Terrain-Precipitation Understanding through AI-driven Knowledge Discovery

Advancing our understanding of climate processes in regions characterized by intricate terrain complexity is a paramount challenge in contemporary climate science, particularly in the context of global climate change. Notably, the scarcity of observational data in these regions has imposed substantial limitations on understanding the nuanced climate dynamics therein. For the first time, utilizing cutting-edge AI-driven knowledge discovery techniques, we have uncovered explicit equations that elucidate the intricate relationship between terrain features and precipitation patterns, illuminating the previously concealed complexities governing these relationships. These equations, thus far undisclosed, exhibit remarkable accuracy compared to conventional empirical models when applied to precipitation data. Building on this foundation, we reveal a phenomenon known as the '1995 turning point,' indicating a significant shift in the terrain-precipitation relationship in approximately 1995, related to the forces of climate change. These equations have practical applications, particularly in achieving fine-scale downscaling precipitation predictions from low-resolution future climate data. This capability provides invaluable insights into the expected changes in precipitation patterns across diverse terrains under future climate scenarios.