Abstract
Abstract. Microphysical processes are important for the development of clouds and thus Earth's climate. For example, turbulent fluctuations in the water vapor mixing ratio, r, and temperature, T, cause fluctuations in the saturation ratio, S. Because S is the driving factor in the condensational growth of droplets, fluctuations may broaden the cloud droplet size distribution due to individual droplets experiencing different growth rates. The small-scale turbulent fluctuations in the atmosphere that are relevant to cloud droplets are difficult to quantify through field measurements. We investigate these processes in the laboratory using Michigan Tech's Π Chamber. The Π Chamber utilizes Rayleigh–Bénard convection (RBC) to create the turbulent conditions inherent in clouds. In RBC it is common for a large-scale circulation (LSC) to form. As a consequence of the LSC, the temperature field of the chamber is not spatially uniform. In this paper, we characterize the LSC in the Π Chamber and show how it affects the shape of the distributions of r, T, and S. The LSC was found to follow a single roll with an updraft and downdraft along opposing walls of the chamber. Near the updraft (downdraft), the distributions of T and r were positively (negatively) skewed. At each measuring position, S consistently had a negatively skewed distribution, with the downdraft being the most negative.
Highlights
The effects that clouds have on Earth’s climate system are quite sensitive to the details of processes that occur on scales much smaller than the cloud as a whole
In this paper we describe the basic characteristics of the flow in the chamber, including the large-scale circulation, because of the importance of these quantities on the distribution of temperature and water vapor and on the saturation ratio
We have shown that a path-averaged measurement will underestimate the turbulent fluctuations
Summary
The effects that clouds have on Earth’s climate system are quite sensitive to the details of processes that occur on scales much smaller than the cloud as a whole. A laboratory setting, where the effects of fluctuations in S on activation and the drop size distribution can be quantified (Chandrakar et al, 2016, 2017, 2020b; Prabhakaran et al., 2020), is one way some of the enduring questions associated with growth of cloud droplets can be addressed. In this paper we describe the basic characteristics of the flow in the chamber, including the large-scale circulation, because of the importance of these quantities on the distribution of temperature and water vapor and on the saturation ratio. We present measurements of water vapor concentration, temperature, and the saturation ratio, S, at different locations in the LSC of the Chamber for both dry (S < 1) and moist (S > 1) convection
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