Print Email Facebook Twitter Countergradient momentum flux in the presence of rolls in the atmospheric boundary layer Title Countergradient momentum flux in the presence of rolls in the atmospheric boundary layer Author Mak, Ho Yi Lydia (TU Delft Civil Engineering & Geosciences) Contributor de Roode, S.R. (mentor) Jansson, F.R. (mentor) Nuijens, Louise (graduation committee) Degree granting institution Delft University of Technology Programme Applied Earth Sciences Date 2023-03-14 Abstract In the atmospheric boundary layer, when surface heat flux is small and mean wind shear is strong, horizontal convective rolls that are elongated along the wind shear are formed. This study attempts to explain the asymmetry of rolls in terms of turbulence using large-eddy simulations. A pressure gradient in the north-south y direction is applied, which results in an east-west geostrophic wind. It is shown that the turbulent kinetic energy components in the x and y directions are not equal when rolls develop. In addition, a countergradient regime is present for vertical momentum flux in the y direction in convective boundary layer with rolls. In the countergradient regime, the wind variance in the y direction is destroyed, contrary to being produced in the x direction. The presence of a countergradient regime for v'w' but not u'w' suggests that the eddy viscosity in the x and y directions would be rather different, and even become negative for v'w'. Thus, the existing parameterization scheme in global atmospheric models may need to be modified. However, the design of an improved parameterization scheme is non-trivial as the countergradient regime is non-stationary when stability decreases, while it does not exist in neutral or stable boundary layers with rolls. Subject large-eddy simulationcountergradient momentum fluxhorizontal convective rollsturbulent kinetic energyeddy viscosity To reference this document use: http://resolver.tudelft.nl/uuid:4343c799-d1c7-4cbc-8c11-79d6b4623a25 Bibliographical note Programme: Applied Earth Sciences and Geoscience and Remote Sensing Part of collection Student theses Document type student report Rights © 2023 Ho Yi Lydia Mak Files PDF report_lmak.pdf 12.54 MB Close viewer /islandora/object/uuid:4343c799-d1c7-4cbc-8c11-79d6b4623a25/datastream/OBJ/view