The stable atmospheric boundary layer over snow‐covered sea ice: Model evaluation with fine‐scale ISOBAR18 observations

Lorenz, Torge; Mayer, Stephanie; Kral, Stephan T.; Suomi, Irene; Steeneveld, G.J.; Holtslag, A.A.M.

doi:10.1002/qj.4293

Cited by 2 publications

(1 citation statement)

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“…According to Mahrt (2014) the "fundamental features of the very stable boundary layer still remain a mystery". In this context, the simulation of the very SBL and the representation of transitions from and to such a regime by planetary boundary layer parameterizations is a major micrometeorological challenge that limits the quality of the representation of the mean state of the atmosphere near the surface in both numerical weather prediction (NWP) and climate models today {(van de Battisti et al 2017;Baas et al 2019;Holdsworth and Monahan 2019;Lapo et al 2019;Maroneze et al 2019Maroneze et al , 2021Lorenz et al 2022;Kähnert et al 2022). At the same time, the weakly SBL is well described by Monin-Obukhov similarity theory and, for this reason, is comparatively well simulated and represented by numerical planetary boundary layer (PBL) parametrization schemes (Mahrt 2014).…”

Section: Introductionmentioning

confidence: 99%

A New Stable Boundary Layer Parameterization for Numerical Weather Prediction Models: A Heat Flux Budget Approach

Maroneze

Costa

Acevedo

et al. 2023

Boundary-Layer Meteorol

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The present study introduces a new boundary layer parameterization for weather and forecasting models. It is implemented here as a boundary layer module in Weather Research and Forecasting (WRF) model. The main novelty in the new scheme is that it includes prognostic equations for the heat flux and temperature variance, being the first WRF boundary layer scheme with that feature. This is specially aimed at improving the representation of nocturnal stable boundary layer and of its turbulence regimes, weakly and very stable. The effort is supported by previous studies that found that the two regimes and the transitions between them are better represented by simplified numerical schemes that represent the interactions between the surface and the air adjacent to it when the heat flux and temperature variance are solved prognostically. The results show that the two regimes are adequately simulated by the new scheme. Such an evaluation is presented in terms of the relationship between the turbulence velocity scale and mean wind speed, of the dependence of the potential temperature gradient near the surface and the mean wind speed, and by the relationship between flux and gradient Richardson numbers. In the new scheme, the relationship between thermal structure and the mean and turbulent flows arises naturally from the heat flux prognostic equation, not being arbitrarily imposed by an empirical stability function.

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