How Does the Choice of the Lower Boundary Conditions in Large-Eddy Simulations Affect the Development of Dispersive Fluxes Near the Surface?

authored by
Luise Wanner, Frederik De Roo, Matthias Sühring, Matthias Mauder
Abstract

Large-eddy simulations (LES) are an important tool for investigating the longstanding energy-balance-closure problem, as they provide continuous, spatially-distributed information about turbulent flow at a high temporal resolution. Former LES studies reproduced an energy-balance gap similar to the observations in the field typically amounting to 10–30% for heights on the order of 100 m in convective boundary layers even above homogeneous surfaces. The underestimation is caused by dispersive fluxes associated with large-scale turbulent organized structures that are not captured by single-tower measurements. However, the gap typically vanishes near the surface, i.e. at typical eddy-covariance measurement heights below 20 m, contrary to the findings from field measurements. In this study, we aim to find a LES set-up that can represent the correct magnitude of the energy-balance gap close to the surface. Therefore, we use a nested two-way coupled LES, with a fine grid that allows us to resolve fluxes and atmospheric structures at typical eddy-covariance measurement heights of 20 m. Under different stability regimes we compare three different options for lower boundary conditions featuring grassland and forest surfaces, i.e. (1) prescribed surface fluxes, (2) a land-surface model, and (3) a land-surface model in combination with a resolved canopy. We show that the use of prescribed surface fluxes and a land-surface model yields similar dispersive heat fluxes that are very small near the vegetation top for both grassland and forest surfaces. However, with the resolved forest canopy, dispersive heat fluxes are clearly larger, which we explain by a clear impact of the resolved canopy on the relationship between variance and flux–variance similarity functions.

Organisation(s)
Institute of Meteorology and Climatology
External Organisation(s)
Karlsruhe Institute of Technology (KIT)
Meteorologisk Institutt (MET)
Type
Article
Journal
Boundary-Layer Meteorology
Volume
182
Pages
1-27
ISSN
0006-8314
Publication date
01.2022
Publication status
Published
Peer reviewed
Yes
ASJC Scopus subject areas
Atmospheric Science
Sustainable Development Goals
SDG 15 - Life on Land
Electronic version(s)
https://doi.org/10.15488/12881 (Access: Open)
https://doi.org/10.1007/s10546-021-00649-7 (Access: Open)