Resolved-scale turbulence in the atmospheric surface layer from a large eddy simulation

The filtered radiative transfer equation has been solved without subgrid-scale model and compared to apriori estimations from direct numerical simulation of statistically stationary homogeneous isotropic turbulence. The importance of the large eddy simulation non-resolved scales on the thermal radia

The dynamics of flow and heat transfer on internally heated multi-layered matrix of cubes mounted on one of the walls of a plane channel is investigated by numerical simulation using a finite-volume unstructured solver. The fluid flow and convective heat transfer were solved by large eddy simulation

The in¯uence of a high free-stream turbulent ®eld on a spatially evolving turbulent ¯at plate boundary layer is investigated using large eddy simulation (LES) with a dynamic mixed subgrid-scale model. The evolutions of skin friction, heat transfer coecient, and ¯ow and thermal ®eld are presented and

## Abstract This study investigates the Large‐Eddy Simulation (LES) technique in the diurnally varying atmospheric boundary layer in conditions of realistic environmental forcing. The initial settings of meteorological fields are obtained by ‘ingesting’ into the LES domain the vertical profiles of

In turbulent flow, the normal procedure has been to seek means u of the fluid velocity u rather than the velocity itself. If these means are defined by local spacial averaging with an averaging radius of ␦ the approach is known as large eddy Ž . simulation, and u denotes the eddies of size 0 ␦ and l