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Air pollution modeling over very complex terrain: An evaluation of WRF-Chem over Switzerland for two one-year periods
JournalArticle (Originalarbeit in einer wissenschaftlichen Zeitschrift)
 
ID 1919732
Author(s) Ritter, Mathias; Müller, Mathias D.; Tsai, Ming-Yi; Parlow, Eberhard
Author(s) at UniBasel Parlow, Eberhard
Müller, Mathias
Ritter, Mathias
Tsai, Ming-Yi
Year 2013
Title Air pollution modeling over very complex terrain: An evaluation of WRF-Chem over Switzerland for two one-year periods
Journal Atmospheric research
Volume 132–133
Pages / Article-Number 209–222
Keywords air pollution modeling, air quality, WRF-Chem, Switzerland, PolluMap
Abstract

The fully coupled chemistry module (WRF-Chem) within the Weather Research and Forecasting (WRF) model has been implemented over a Swiss domain for the years 2002 and 1991. The very complex terrain requires a high horizontal resolution (2 x 2 km(3)), which is achieved by nesting the Swiss domain into a coarser European one. The temporal and spatial distribution of O-3, NO2 and PM10 as well as temperature and solar radiation are evaluated against ground-based measurements. The model performs well for the meteorological parameters with Pearson correlation coefficients of 0.92 for temperature and 0.88-0.89 for solar radiation. Temperature has root mean square errors (RMSE) of 330 K and 351 K for 2002 and 1991 and solar radiation has RMSEs of 122.92 and 11635 for 2002 and 1991, respectively. For the modeled air pollutants, a multi-linear regression post-processing was used to eliminate systematic bias. Seasonal variations of post-processed air pollutants are represented correctly. However, short-term peaks of several days are not captured by the model. Averaged daily maximum and daily values of O-3 achieved Pearson correlation coefficients of 0.69-0.77 whereas averaged NO2 and PM10 had the highest correlations for yearly average values (0.68-0.78). The spatial distribution reveals the importance of PMic, advection from the Po valley to southern Switzerland (Ticino). The absolute errors are ranging from -10 to 15 mu g/m3 for ozone, -9 to 3 mu g/m(3) for NO2 and -4 to 3 mu g/m(3) for PM10. However, larger errors occur along heavily trafficked roads, in street canyons or on mountains. We also compare yearly modeled results against a dedicated Swiss dispersion model for NO2 and PMio. The dedicated dispersion model has a slightly better statistical performance, but WRF-Chem is capable of computing the temporal evolution of three-dimensional data for a variety of air pollutants and meteorological parameters. Overall, WRF-Chem with the application of post-processing algorithms can produce encouraging statistical values over very complex terrain which are competitive with similar studies.

Publisher Elsevier
ISSN/ISBN 0169-8095
edoc-URL http://edoc.unibas.ch/dok/A6146181
Full Text on edoc No
Digital Object Identifier DOI 10.1016/j.atmosres.2013.05.021
ISI-Number WOS:000326141500018
Document type (ISI) Article
 
   

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