Abstract
Abstract. The properties of a warm convective cloud are determined by the competition between the growth and dissipation processes occurring within it. One way to observe and follow this competition is by partitioning the cloud to core and margin regions. Here we look at three core definitions, namely positive vertical velocity (Wcore), supersaturation (RHcore), and positive buoyancy (Bcore), and follow their evolution throughout the lifetime of warm convective clouds. Using single cloud and cloud field simulations with bin-microphysics schemes, we show that the different core types tend to be subsets of one another in the following order: Bcore⊆RHcore⊆Wcore. This property is seen for several different thermodynamic profile initializations and is generally maintained during the growing and mature stages of a cloud's lifetime. This finding is in line with previous works and theoretical predictions showing that cumulus clouds may be dominated by negative buoyancy at certain stages of their lifetime. The RHcore–Wcore pair is most interchangeable, especially during the growing stages of the cloud. For all three definitions, the core–shell model of a core (positive values) at the center of the cloud surrounded by a shell (negative values) at the cloud periphery applies to over 80 % of a typical cloud's lifetime. The core–shell model is less appropriate in larger clouds with multiple cores displaced from the cloud center. Larger clouds may also exhibit buoyancy cores centered near the cloud edge. During dissipation the cores show less overlap, reduce in size, and may migrate from the cloud center.
Highlights
Clouds are important players in the climate system (Trenberth et al, 2009) and currently constitute one of the largest uncertainties in climate and climate change research (IPCC, 2013)
A time step of 1 s is chosen for dynamical computations, and 0.5 s is chosen for the microphysical computations
In this paper we study the partition of warm convective clouds to core and margin according to three different definitions: (i) positive vertical velocity (Wcore), (ii) relative humidity supersaturation (RHcore), and (iii) positive buoyancy (Bcore), with emphasis on the differences between those definitions
Summary
Clouds are important players in the climate system (Trenberth et al, 2009) and currently constitute one of the largest uncertainties in climate and climate change research (IPCC, 2013). One of the reasons for this large uncertainty is the complexity created by opposing processes that occur at the same time but in different locations within a cloud. Changes in thermodynamic or microphysical (aerosol) conditions impact the processes in both regions (sometimes in different ways) and the resultant total cloud properties (Dagan et al, 2015). To better understand cloud properties and their evolution in time, it is necessary to understand the interplay between physical processes within the core and margin regions (and the way they are affected by perturbations in the environmental conditions). Considering convective clouds, there are several objective measures that have been used in previous works for separating a cloud’s core from its margins (this will be referred to as physical cores hereafter). Studies on warm cumulus clouds have defined the clouds’ core as parts with positive buoyancy and positive updrafts (Dawe and Austin, 2012; de Roode et al, 2012; Heus and Jonker, 2008; Siebesma and Cuijpers, 1995)
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