Land-Use Improvements in the Weather Research and Forecasting Model over Complex Mountainous Terrain and Comparison of Different Grid Sizes

Weather forecasts over mountainous terrain are challenging due to the complex topography that is necessarily smoothed by actual local-area models. As complex mountainous territories represent 20% of the Earth’s surface, accurate forecasts and the numerical resolution of the interaction between the s...

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Bibliographic Details
Published in:Boundary-layer meteorology 2021-08, Vol.180 (2), p.319-351
Main Authors: Golzio, Alessio, Ferrarese, Silvia, Cassardo, Claudio, Diolaiuti, Gugliemina Adele, Pelfini, Manuela
Format: Article
Language:English
Subjects:
Air temperature
Atmospheric boundary layer
Atmospheric models
Atmospheric Protection/Air Quality Control/Air Pollution
Atmospheric Sciences
Boundary layers
Datasets
Digital Elevation Models
Earth and Environmental Science
Earth Sciences
Earth surface
Elevation
Enthalpy
Geological surveys
Glaciers
Heat
Heat flux
Heat transfer
Land cover
Land use
Latent heat
Meteorological research
Meteorology
Mountains
Numerical weather forecasting
Planetary boundary layer
Radar
Research Article
Resolution
Sensible heat
Soil layers
Soil moisture
Soil temperature
Spectroradiometers
Surveying
Terrain
Topography
Weather
Weather forecasting
Weather stations
Wind speed
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Summary:Weather forecasts over mountainous terrain are challenging due to the complex topography that is necessarily smoothed by actual local-area models. As complex mountainous territories represent 20% of the Earth’s surface, accurate forecasts and the numerical resolution of the interaction between the surface and the atmospheric boundary layer are crucial. We present an assessment of the Weather Research and Forecasting model with two different grid spacings (1 km and 0.5 km), using two topography datasets (NASA Shuttle Radar Topography Mission and Global Multi-resolution Terrain Elevation Data 2010, digital elevation models) and four land-cover-description datasets (Corine Land Cover, U.S. Geological Survey land-use, MODIS30 and MODIS15, Moderate Resolution Imaging Spectroradiometer land-use). We investigate the Ortles Cevadale region in the Rhaetian Alps (central Italian Alps), focusing on the upper Forni Glacier proglacial area, where a micrometeorological station operated from 28 August to 11 September 2017. The simulation outputs are compared with observations at this micrometeorological station and four other weather stations distributed around the Forni Glacier with respect to the latent heat, sensible heat and ground heat fluxes, mixing-layer height, soil moisture, 2-m air temperature, and 10-m wind speed. The different model runs make it possible to isolate the contributions of land use, topography, grid spacing, and boundary-layer parametrizations. Among the considered factors, land use proves to have the most significant impact on results.
ISSN:0006-8314
1573-1472
DOI:10.1007/s10546-021-00617-1