Diverging Trends in Rain-On-Snow Over High Mountain Asia

Rain-on-snow (ROS) over snow-dominated regions such as High Mountain Asia (HMA) modulates snowmelt and runoff and is key contributor in influencing water availability and hazards (e.g., floods and landslides). We studied the trends in ROS in HMA over the past two decades from 2001 to 2018 using the land surface model Noah-MP driven by an ensemble precipitation data set. Our results show that changes in precipitation phase and rainfall are altering ROS. Because of the strong physical heterogeneity and atmospheric dynamics of HMA, ROS characteristics and trends are region-dependent and ROS occurs predominantly over the Indus, Ganges-Brahmaputra, and northwestern basins. In the Indus, ROS representing similar to 5% of the annual precipitation and similar to 20% of the annual snowmelt, has an increasing trend. This is contrary to the Ganges-Brahmaputra characterized by decreasing ROS trends, where it represents similar to 11% of the annual precipitation and similar to 60% of the annual snowmelt. In the northwestern basins, ROS has bidirectional trends due to elevation patterns and trends in rainfall, and it constitutes similar to 5 to similar to 10% of the annual precipitation. Increasing trends in ROS over Indus contribute to reducing the snowpack in late summer, with concerns of reduced water availability and increased groundwater exploitation. Similarly, because of its high amount and contribution to snowmelt, the decreasing ROS trends in the Ganges-Brahmaputra will have consequences of decreased recharge from the headwaters and exacerbated use of groundwater unless increasing trends in rainfall compensate for the decreasing snowmelt. These results provide new insights on ROS-driven changes in the hydrological cycle over HMA.

Automated summary

Rain-on-snow (ROS) in High Mountain Asia (HMA) has significant impacts on snowmelt and runoff, affecting water availability and hazards. Our study reveals that changes in precipitation phase and rainfall are modifying ROS characteristics and trends in HMA. The Indus basin shows an increasing trend in ROS, while the Ganges-Brahmaputra basin exhibits a decreasing trend. The northwestern basins show bidirectional trends in ROS due to elevation patterns and rainfall trends. These findings provide valuable insights into the hydrological cycle changes driven by ROS in HMA.