One of the important roles of the PBL is to transport moisture from the surface to the cloud layer. However, how this transport process can be accounted for in cloud-resolving models (CRMs) is not sufficiently clear and has rarely been examined. A typical CRM can resolve the bulk feature of large convection systems but not the small-scale convection and turbulence motions that carry a large portion of the moisture fluxes. This study uses a large-eddy simulation of a tropical deep-convection system as a benchmark to examine the subgrid-scale (SOS) moisture transport into a cloud system.
It is shown that most of the PBL moisture transport to the cloud layer occurs in the areas under low-level updrafts, with rain, or under cloudy skies, although these PBL regimes may cover only a small fraction of the entire cloud-system domain. To develop SOS parameterizations to represent the spatial distribution of this moisture transport in CRMs, three models are proposed and tested. An updraft-downdraft model performs exceptionally well, while a statistical-closure model and a local-gradient model are less satisfactory but still perform adequately. Each of these models, however, has its own closure issues to be addressed. The updraft-downdraft model requires a scheme to estimate the mean SOS updraft-downdraft properties, the statistical-closure model needs a scheme to predict both SOS vertical-velocity and moisture variances, while the local-gradient model requires estimation of the SOS vertical-velocity variance.

• 出版日期2012-11