Impact of diurnal temperature and relative humidity hysteresis on atmospheric dryness in changing climates
Ching-Hung Shih, Yi‐Shin Jang, Tzu-Ying Yang, Cho‐ying Huang, Jehn‐Yih Juang, Min‐Hui Lo
Abstract
Vapor pressure deficit (VPD), a key indicator of atmospheric dryness, is strongly influenced by diurnal cycles of temperature ( T ) and relative humidity (RH). While these cycles are typically inversely locked in-phase, recent research has identified diurnal hysteresis, characterized by a time lag between T and RH; yet, its impact on VPD under changing climates remains poorly understood. In this study, we examine how diurnal T /RH hysteresis modulates VPD across different climates using observational data alongside high-resolution reanalysis and simulations. Here, we find that regions exhibiting strong diurnal T /RH hysteresis, especially in some waterside and montane regions, experience earlier daily VPD peaks. We also demonstrate that global warming weakens diurnal T /RH hysteresis, leading to amplified VPD increasing trends and greater ecosystem stress. These results highlight the need for improved representation of diurnal T /RH interactions in climate models to better predict atmospheric dryness and its impacts on land-atmosphere feedbacks, ecosystems, and regional water cycles.