Abstract

Abstract. This second part of a numerical study on shallow-cumulus dilution focuses on the sensitivity of cloud dilution to changes in the vertical wind profile. Insights are obtained through large-eddy simulations of maritime and continental cloud fields. In these simulations, the speed of the initially uniform geostrophic wind and the strength of geostrophic vertical wind shear in the cloud and subcloud layer are varied. Increases in the cloud-layer vertical wind shear (up to 9 ms-1km-1) lead to 40 %–50 % larger cloud-core dilution rates compared to their respective unsheared counterparts. When the background wind speed, on the other hand, is enhanced by up to 10 m s−1 and subcloud-layer vertical wind shear develops or is initially prescribed, the dilution rate decreases by up to 25 %. The sensitivities of the dilution rate are linked to the updraft strength and the properties of the entrained air. Increases in the wind speed or vertical wind shear result in lower vertical velocities across all sets of experiments with stronger reductions in the cloud-layer wind shear simulation (27 %–47 %). Weaker updrafts are exposed to mixing with the drier surrounding air for a longer time period, allowing more entrainment to occur (i.e., the “core-exposure effect”). However, reduced vertical velocities, in concert with increased cloud-layer turbulence, also assist in widening the humid shell surrounding the cloud cores, leading to entrainment of more humid air (i.e., the “core–shell dilution effect”). In the experiments with cloud-layer vertical wind shear, the core-exposure effect dominates and the cloud-core dilution increases with increasing shear. Conversely, when the wind speed is increased and subcloud-layer vertical wind shear develops or is imposed, the core–shell dilution effect dominates to induce a buffering effect. The sensitivities are generally stronger in the maritime simulations, where weaker sensible heat fluxes lead to narrower, more tilted, and, therefore, more suppressed cumuli when cloud-layer shear is imposed. Moreover, in the experiments with subcloud wind shear, the weaker baseline turbulence in the maritime case allows for a larger turbulence enhancement, resulting in a widening of the transition zones between the cores and their environment, leading to the entrainment of more humid air.

Highlights

  • Shallow cumuli are strongly affected by the ingestion of surrounding air, a process known as entrainment

  • The present study focuses on the sensitivity of shallowcumulus dilution to the geostrophic vertical wind profile

  • The BOMEX horizontal domain size of 6.4 × 6.4 km2 is left unchanged from Siebesma et al (2003), while the Atmospheric Radiation Measurement (ARM)-Southern Great Plains (SGP) domain size is doubled from 6.4 × 6.4 km2 in Brown et al (2002) to 12.8 × 12.8 km2 to capture the larger-scale circulations of this cloud field

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Summary

Introduction

Shallow cumuli are strongly affected by the ingestion of surrounding air, a process known as entrainment. While vertical wind shear is known to organize deep convection into intense manifestations (e.g., supercell thunderstorms), it has more subtle effects on shallow cumuli In principle, this shear can enhance cloud entrainment via increased turbulent mixing and/or stronger cloud-relative winds (e.g., Markowski and Richardson, 2010). The impacts of vertical wind shear on ε remain unclear Both numerical simulations (Brown, 1999; Lin, 1999; Helfer et al, 2020) and observational ε retrievals (Kirshbaum and Lamer, 2021) suggest minimal sensitivity of ε to cloud-layer shear.

Model configuration
LES experiments
The CTRL cases
Sensitivity to cloud-layer vertical wind shear
Sensitivity to vertically uniform geostrophic winds
Sensitivity to subcloud-layer shear
Cloud-core vertical velocity
Properties of entrained air
Empirical relationship
Conclusions

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