Downscaling system for modeling of atmospheric composition on regional, urban and street scales

Roman Nuterman,Alexander Baklanov,Alexander Mahura,Ashraf Zakey,Bjarne Amstrup

doi:10.5194/acp-21-11099-2021

Abstract

Abstract. In this study, the downscaling modeling chain for prediction of weather and atmospheric composition is described and evaluated against observations. The chain consists of interfacing models for forecasting at different spatiotemporal scales that run in a semi-operational mode. The forecasts were performed for European (EU) regional and Danish (DK) subregional-urban scales by the offline coupled numerical weather prediction HIRLAM and atmospheric chemical transport CAMx models, and for Copenhagen city-street scale by the online coupled computational fluid dynamics M2UE model. The results showed elevated NOx and lowered O3 concentrations over major urban, industrial, and transport land and water routes in both the EU and DK domain forecasts. The O3 diurnal cycle predictions in both these domains were equally good, although O3 values were closer to observations for Denmark. At the same time, the DK forecast of NOx and NO2 levels was more biased (with a better prediction score of the diurnal cycle) than the EU forecast, indicating a necessity to adjust emission rates. Further downscaling to the street level (Copenhagen) indicated that the NOx pollution was 2-fold higher on weekends and more than 5 times higher during the working day with high pollution episodes. Despite high uncertainty in road traffic emissions, the street-scale model effectively captured the NOx and NO2 diurnal cycles and the onset of elevated pollution episodes. The demonstrated downscaling system could be used in future online integrated meteorology and air quality research and operational forecasting, as well as for impact assessments on environment, population, and decision making for emergency preparedness and safety measures planning.

Highlights

Progress in numerical weather and atmospheric composition modeling and continuously increasing supercomputing power make it possible to perform downscaling and nesting from the global to the local scales, reaching necessary horizontal and vertical resolutions for very detailed local meteorology and pollution forecasts
The goal of this paper is to demonstrate and evaluate the applicability of the downscaling system coupled with computational fluid dynamics model on the operational modeling of an acute air pollution episode
The example of the downscaling modeling chain realized in this study in a semi-operational mode with coupled High-Resolution Limited Area Model (HIRLAM)+Comprehensive Air Quality Model with Extensions (CAMx)+M2UE models is described and evaluated with a focus on Denmark and Copenhagen for a specific meteorological situation

Summary

Introduction

Progress in numerical weather and atmospheric composition modeling and continuously increasing supercomputing power make it possible to perform downscaling and nesting from the global to the local scales, reaching necessary horizontal and vertical resolutions for very detailed local meteorology and pollution forecasts. Global- and regionalscale atmospheric chemistry transport (ACT) modeling systems were actively developed and applied during the last decade These were developed and applied within the frameworks of multiple EU FP6, FP7 and H2020 Monitoring of Atmospheric Composition and Climate (MACC) projects (Hollingsworth et al, 2008; Simmons, 2010; Peuch et al, 2014, 2016). Such systems mostly simulate the regional background of air pollution, for instance, in the Copernicus Atmosphere Monitoring Service (CAMS; Grasso, 2017). As a matter of fact, urban and street air pollution is usually several times higher than the pollution at regional scale over suburbs and rural areas and is mostly associated with both local emission sources (Falasca and Curci, 2018)

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Conclusion