hide
Free keywords:
RADIATION BUDGET EXPERIMENT; LOW STRATIFORM CLOUDS; COLD-AIR OUTBREAK; MIXED-LAYER; MODEL; ENTRAINMENT; SENSITIVITY; TURBULENCE; CONVECTION;
TRANSITIONMeteorology & Atmospheric Sciences; large-eddy simulation; stratocumulus; parametric uncertainty analysis;
drizzle;
Abstract:
A large-eddy simulation (LES) model has been used to study a nocturnal stratocumulus-topped marine atmospheric boundary layer. The main objectives of our study have been first to investigate the statistical significance of LES-derived data products. Second, to test the sensitivity of our LES results with respect to the representation of subgrid-scale mixing and microphysical processes, and third to evaluate and to quantify the parametric uncertainty arising from the incomplete knowledge of the environmental parameters that are required to specify the initial and boundary conditions of a particular case study. Model simulations were compared with observations obtained in solid stratocumulus during the third flight of the first 'Lagrangian' experiment of the Atlantic Stratocumulus Transition Experiment (ASTEX). Based on these simulations the following conclusions could be drawn. Resolution (50 x 50 x 25 m(3)) and domain size (3.2 x 3.2 x 1.5 km(3)) of the LES calculations were adequate from a numerical point of view to represent the essential features of the stratocumulus-topped boundary layer. However, the ensemble runs performed in our study to investigate the statistical significance of LES-derived data products demonstrate that the area-time averaging procedure for the second-order moments produces only a low degree of statistical reliability in the model results. This illustrates the necessity of having LES model results that are not only of adequate resolution but also of sufficiently large domain. The impact of different subgrid schemes was small, but the primary effects of drizzle were found to influence the boundary-layer structure in a climatologically significant way. The parametric uncertainty analysis revealed that the largest contribution to the variance of the LES-derived data products is due to the uncertainties in the cloud-top jump of total water mixing ratio and the net radiative forcing. The differences between the model and measurements for most of the simulated quantities were within the modelling uncertainties, but the calculated precipitation rate was found to differ significantly from that derived in the observations.
