Diabatic Rossby Vortex World: Finite-Amplitude Effects in Moist Cyclogenesis

Author(s)

Kohl, Matthieu; O’Gorman, Paul A

Abstract

Diabatic Rossby vortices (DRVs) are a special class of heavily precipitating extratropical cyclone in which latent heating effects play a key role. As such, their dynamics defies the classic mechanism of midlatitude storm formation and poses challenges to modeling and theoretical understanding. Here, we build on recent theoretical advances on the growth of DRV modes in small-amplitude moist instability calculations by exploring the structure of finite-amplitude DRV storms in a hierarchy of models of moist macroturbulence. Simulations of moist quasigeostrophic turbulence show a transition to a DRV-dominated flow (DRV world) when the latent heating is strong. The potential vorticity (PV) structure of the DRVs is similar to the PV structure from small-amplitude DRV modal theory. Simulations of the moist primitive equations also transition to DRV world when both the latent heating is strong and the Rossby number is sufficiently low. At high Rossby numbers, however, the PV structure of storms with strong latent heating is bottom intensified compared to DRV modal theory due to higher-order effects beyond quasigeostrophy, and the macroturbulent flow has both DRV-like storms and frontal structures. A 1D model of the vertical structure of PV is solved for different Rossby numbers and stratification profiles to reconcile the PV structures of DRVs in the simulations, small-amplitude modal theory, and observations.

Date issued

2025-10-01

URI

https://hdl.handle.net/1721.1/165460

Department

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Journal

Journal of the Atmospheric Sciences

Publisher

American Meteorological Society

Citation

Kohl, M., and P. A. O’Gorman, 2025: Diabatic Rossby Vortex World: Finite-Amplitude Effects in Moist Cyclogenesis. J. Atmos. Sci., 82, 2161–2180.

Version: Final published version