Litcius/Paper detail

Increasing contribution of the atmospheric vertical motion to precipitation in a warming climate

Tackseung Jun, David Rind

2024Communications Earth & Environment15 citationsDOIOpen Access PDF

Abstract

Global warming already influences precipitation, with more intense precipitation in many locations. Although the ‘wet-get-wetter, dry-get-drier’ tendency in mean precipitation holds in many locations, the situations for precipitation extremes are more complex, due to changes in dynamic and thermodynamic influences on atmospheric moisture distributions. Here, we build a dynamically interactive atmospheric moisture model for the present (2006–2025) and the future climate (2081–2100), using outputs from coupled ocean-atmosphere general circulation models. We find that the dynamic process of vertical advection of moisture dominates the same-day precipitation, while the smaller impact of the thermodynamic process provides available moisture for several days. As climate warms, we find that the dynamical-induced precipitation more completely exhausts the vertically-integrated moisture and the distribution of the dynamic process’s impact on precipitation exhibits a greater spread in the warmer future. The dynamical process is primarily responsible for more extreme heavy precipitation as climate warms, at all latitudes. Vertical moisture transport that is governed by atmospheric dynamics determines precipitation intensity on the same day, and exhausts the available moisture in the atmosphere more completely as the climate warms, according to an interactive atmospheric moisture model informed by climate model output.

Topics & Concepts

PrecipitationEnvironmental scienceClimatologyAtmospheric sciencesGlobal warmingClimate changeMeteorologyGeographyGeologyOceanographyClimate variability and modelsMeteorological Phenomena and SimulationsCryospheric studies and observations