October 21, 2019
Highlight

Looking at Monsoon Rainfall Through a New Lens

Researchers discovered different hydrological characteristics between Indian and East/Southeast Asian monsoon systems in a warmer climate

Monsoon

The Science


Summer monsoon rainfall provides the lifeline for agriculture in many tropical and subtropical countries. How monsoon precipitation and hydrological extremes could respond to climate warming is of great social and societal importance. Working with university collaborators, researchers from the U.S. Department of Energy’s Pacific Northwest National Laboratory developed and applied a new analysis method—called local water vapor wave activity, or LWA—to examine how hydrological extremes over Asian monsoon regions will change in the future. They found that a metric for precipitation extremes derived from LWA analysis increased in both the Indian and East/Southeast Asian monsoon regions. Meanwhile, the rate at which water vapor cycled through the atmosphere strengthened in the latter, but not the former, region.


The Impact
This research showcases the application of LWA analysis to tropical monsoon systems. This LWA diagnostic allows for more rigorous study of hydrological extremes at a regional scale, with the resultant LWA sink as a useful metric for precipitation extremes. The distinct characteristics in the hydrological cycling rate imply differing dynamical mechanisms governing precipitation extremes between Indian and East/Southeast Asian monsoons.


Summary
Globally, the atmosphere may be treated as a “reservoir” of moisture, with precipitation acting as a moisture sink and evaporation a moisture source, and thus the concept of hydrological cycle is well suited for globally integrated moisture. However, this global perspective cannot be readily carried over to regional atmospheric hydrological cycles. In a changing climate, the amount of precipitation that reaches Earth’s surface could fluctuate greatly by region compared to historical trends. Researchers developed an LWA diagnostic method for water vapor to represent local hydrological cycles. They then applied the method to explore the response of hydrological extremes over Asian monsoon systems to a climate warming scenario. Results showed that future water vapor wave activity over the broad Asian monsoon region increased by about 35 percent, largely due to the increase in background moisture. The analysis also found that precipitation extremes measured by the LWA sink of the budget strongly increased in both the Indian and East/Southeast Asian monsoon regions. The hydrological cycling rate, measured by the inverse of the residence time of the column moisture, showed distinct features between the two regions, suggesting different dynamical effects. 


PI Contact
L. Ruby Leung, Pacific Northwest National Laboratory, Ruby.Leung@pnnl.gov 


Funding
The U.S. Department of Energy Office of Science, Biological and Environmental Research supported this research as part of the Regional and Global Climate Modeling program. The National Natural Science Foundation of China (Grants 41475092, 41621005, and 41775073), China Scholarship Council, and Jiangsu Collaborative Innovation Center for Climate Change supported D.X. The National Natural Science Foundation of China (Grants 41475092 and 41621005) supported Y.Z.
 

Revised: October 21, 2019 | Published: December 20, 2018

D. Xue, J. Lu, L.R. Leung, and Y. Zhang, “Response of the Hydrological Cycle in Asian Monsoon Systems to Global Warming Through the Lens of Water Vapor Wave Activity Analysis.” Geophysical Research Letters 45(21), 11,904−11,912 (2018). [https://doi.org/10.1029/2018GL078998].