Clear-sky stable boundary layers with low winds over snow-covered surfaces. Part 1: WRF model evaluation

In this article, we evaluate the Weather Research and Forecasting (WRF) mesoscale meteorological model for stable conditions in clear skies with low wind speeds. Three contrasting terrains with snow-covered surfaces are considered, namely Cabauw (Netherlands, snow over grass), Sodankylä (Finland, sn...

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Bibliographic Details
Published in:Quarterly Journal of the Royal Meteorological Society
Main Authors: Sterk, H. A. M., Steeneveld, G. J., Vihma, T., Anderson, P. S., Bosveld, F. C., Holtslag, A. A. M.
Format: Article in Journal/Newspaper
Language:English
Published: 2015
Subjects:
stable boundary layer
single-column model
WRF
model evaluation
snow surface
low wind speeds
7ref2021
Sodankylä
Antarc*
Antarctica
Ice Shelf
Online Access:https://pure.uhi.ac.uk/en/publications/e68b95e9-0b65-4c4b-b623-ce4e377209d6
https://doi.org/10.1002/qj.2513
Description
Summary:In this article, we evaluate the Weather Research and Forecasting (WRF) mesoscale meteorological model for stable conditions in clear skies with low wind speeds. Three contrasting terrains with snow-covered surfaces are considered, namely Cabauw (Netherlands, snow over grass), Sodankylä (Finland, snow over a needle-leaf forest) and Halley (Antarctica, snow over an ice shelf). We used the full three-dimensional (3D) model and the single-column versions of the WRF model. The single-column model (SCM) was driven by realistic forcings of the WRF–3D field. Several sets of SCM forcings were tested: A, no advection; B, varying geostrophic wind in time; C, momentum advection in addition to B; D, temperature and moisture advection in addition to C; E, forcing the SCM field to the 3D field above a threshold height. The WRF–3D model produced good results overall for wind speed, but the near-surface temperatures and specific humidity were overestimated for Cabauw and Sodankylä and underestimated for Halley. Prescribing advection for momentum, temperature and moisture gave the best results for the WRF–SCM and simulations deviated strongly from reality without advection. Nudging the SCM field to the 3D field above a threshold height led to an unrealistic behaviour of the variables below this height and is not recommended. Detailed prescription of the surface characteristics, e.g. adjusting the snow cover and vegetation fraction, improved the 2 m temperature simulation. For all three sites, the simulated temperature and moisture inversion were underestimated, though this improved when prescribing advection. Overall, in clear-sky conditions, the stable boundary layer over snow and ice can be modelled to a good approximation if all processes are taken into account at high resolution and if land surface properties are carefully prescribed.

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