Abstract
Abstract Latent cooling by evaporating or melting hydrometeors has recently been shown to contribute to the positive low-level potential vorticity (PV) anomaly below the layer of latent heating in midlatitude cyclones. While the low-level PV anomaly might be intensified by latent cooling, the influence on the overall baroclinic development remains unclear. Including both latent heating and cooling in the Eady model, this study finds that latent cooling reduces baroclinic growth. While the PV anomaly between the layers of latent cooling and heating increases for realistic heating intensities, the PV anomaly at the top of the heating layer decreases, as latent heating is weakened because of reduced vertical motion within the cyclone. Consequently, the relative contribution from diabatic heating to the generation of eddy available potential energy decreases when latent cooling is included. Thus, despite the recently emphasized role of evaporation for the low-level PV anomaly in developing cyclones, the overall effect of latent cooling is detrimental to baroclinic growth.
Highlights
Latent heating has been shown to increase the growth rate of midlatitude cyclones while their horizontal scale is reduced (e.g., Manabe 1956; Craig and Cho 1988; Snyder and Lindzen 1991; Moore and Montgomery 2004)
We investigate the influence of latent cooling on the energetics, potential vorticity (PV) distribution, and baroclinic growth using a diabatic extension of the quasigeostrophic (QG) Eady (1949) model
Including diabatic effects representing both midtropospheric latent heating and low-level latent cooling with heating intensities comparable to realistic midlatitude cyclones into the Eady model, we find that latent cooling reduces baroclinic growth and shifts the most unstable mode to longer wavelengths
Summary
Latent heating has been shown to increase the growth rate of midlatitude cyclones while their horizontal scale is reduced (e.g., Manabe 1956; Craig and Cho 1988; Snyder and Lindzen 1991; Moore and Montgomery 2004). This decrease in vertical motion is in accordance with a case study of midlatitude cyclones by Martínez-Alvarado et al (2016) and with the decrease in absolute latent. We split the diabatic term into components due to latent heating Ghe and latent cooling Gce
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