Abstract
The formation of longitudinal vortex rolls in the planetary boundary layer (PBL) is investigated by means of perturbation analysis. The method is the same as that used by previous authors who have investigated the instability of a laminar Ekman layer. To study the instability of the turbulent boundary layer of the atmosphere, vertical profiles are needed of the eddy viscosity and of the two components of the basic flow. These profiles have been obtained by a numerical PBL-model; they are universal for z≫z 0. (However, the stability equations are not completely universal, i.e., independent of the external parameters). For each thermal stratification, expressed by the internal stratification parameter Μ, one has a set of three consistent profiles.
The numerical solution of the stability equations gives the critical values and the perturbation growth rates as functions of thermal stratification Μ and of the surface Rossby number Ro0. This is in contrast to the case of a laminar Ekman layer, where the instability depends on a Reynolds number only, which makes atmospheric applications difficult. The most unstable perturbations are found for Ro0 = 1 × 106 approximately, which is in the range of surface Rossby numbers observed in the atmosphere. However, considering vortex rolls oriented in the direction of the surface stress, the instability is found to be ‘universal’, i.e., independent of the external parameters combined in the surface Rossby number. With respect to thermal stratification, the results show that the instability of the perturbations increases with increasing static stability.
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Etling, D., Wippermann, F. On the instability of a planetary boundary layer with Rossby-number similarity. Boundary-Layer Meteorol 9, 341–360 (1975). https://doi.org/10.1007/BF00230775
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DOI: https://doi.org/10.1007/BF00230775