Abstract
Abstract. In the current global climate models (GCMs), the nonlinearity effect of subgrid cloud variations on the parameterization of warm-rain process, e.g., the autoconversion rate, is often treated by multiplying the resolved-scale warm-rain process rates by a so-called enhancement factor (EF). In this study, we investigate the subgrid-scale horizontal variations and covariation of cloud water content (qc) and cloud droplet number concentration (Nc) in marine boundary layer (MBL) clouds based on the in situ measurements from a recent field campaign and study the implications for the autoconversion rate EF in GCMs. Based on a few carefully selected cases from the field campaign, we found that in contrast to the enhancing effect of qc and Nc variations that tends to make EF > 1, the strong positive correlation between qc and Nc results in a suppressing effect that tends to make EF < 1. This effect is especially strong at cloud top, where the qc and Nc correlation can be as high as 0.95. We also found that the physically complete EF that accounts for the covariation of qc and Nc is significantly smaller than its counterpart that accounts only for the subgrid variation of qc, especially at cloud top. Although this study is based on limited cases, it suggests that the subgrid variations of Nc and its correlation with qc both need to be considered for an accurate simulation of the autoconversion process in GCMs.
Highlights
Marine boundary layer (MBL) clouds cover about one-fifth of Earth’s surface and play an important role in the climate system (Wood, 2012)
In this study we derived the horizontal variations of qc and number concentration (Nc), as well as their covariations in MBL clouds based on the in situ measurements from the recent ACE-ENA campaign, and investigated the implications of subgrid variability as it relates to the enhancement of autoconversion rates
– The observation-based physically complete E that accounts for the covariation of qc and Nc has a robust decreasing trend from cloud base to cloud top, which can be explained by the increasing trend of the qc and Nc correlation from cloud base to cloud top
Summary
Marine boundary layer (MBL) clouds cover about one-fifth of Earth’s surface and play an important role in the climate system (Wood, 2012). A good understanding of the vertical dependence of qc and Nc variation inside MBL clouds will help us understand the limitations in the previous studies, such as Z19, that use the column-integrated products for the study of EF This investigation may be useful for modeling other processes, such as aerosol– cloud interactions, in the GCMs. our main objectives in this study are to (1) better understand the horizontal variations of qc and Nc, their covariation, and the dependence on vertical height in MBL clouds; and (2) elucidate the implications for the EF of the autoconversion parameterization in GCMs. The rest of the paper is organized as follows: we will describe the data and observations used in this study in Sect.
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