4A.5 Changes in the Convective Population and Thermodynamic Environments in Convection-Permitting Regional Climate Simulations over the United States

Tuesday, 9 January 2018: 9:30 AM
Salon F (Hilton) (Austin, Texas)
Kristen Lani Rasmussen, Colorado State Univ, Fort Collins, CO; and A. F. Prein, R. M. Rasmussen, K. Ikeda, and C. Liu

Novel high-resolution convection-permitting regional climate simulations over the U.S. employing the pseudo-global warming approach are used to investigate changes in the convective population and thermodynamic environments in a future climate. Two continuous 13-year simulations were conducted using (1) ERA-Interim reanalysis and (2) ERA-Interim reanalysis plus a climate perturbation for the RCP8.5 scenario. The simulations closely match the observed precipitation diurnal cycle, indicating that they reproduce organized and propagating convection that most climate models cannot adequately represent. This study shows that weak to moderate convection will decrease and strong convection will increase in frequency in a future climate. Analysis of the thermodynamic environments supporting convection shows that both convective available potential energy (CAPE) and convective inhibition (CIN) increase downstream of the Rockies in a future climate. Previous studies suggest that CAPE will increase in a warming climate, however a corresponding increase in CIN acts as a balancing force to shift the convective population by suppressing weak to moderate convection and provides an environment where CAPE can build to extreme levels that may result in more frequent severe convection. An idealized investigation of fundamental changes in the thermodynamic environment was conducted by shifting a standard atmospheric profile by ± 5°C. When temperature is increased, both CAPE and CIN increase in magnitude, while the opposite is true for decreased temperatures. Thus, even in the absence of synoptic and mesoscale variations, a warmer climate will provide more CAPE and CIN that will shift the convective population, likely impacting water and energy budgets on Earth.
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