Abstract
We investigated the effects of wet deposition on secondary inorganic aerosols (SIAs) in urban areas by coupling the wet deposition module with the three-dimensional computational fluid dynamics atmospheric chemistry model (CFD-Chem). We developed a wet deposition model for the microscale model by improving on the global modeling initiative scheme. We evaluated the model by comparing it to the observed washout ratio from the total wet deposition. The simulated washout ratio calculated using the wet scavenging coefficient (WSC) based on the theoretical calculation is six times lower than that observed, suggesting that the wet deposition amount of SIAs from below-cloud scavenging might be underestimated. When we applied the WSC based on field measurements, the washout ratio was much improved; however, it was slightly overestimated compared to the observed rate. Therefore, we estimated the optimal WSC for SIAs in the urban area using a linear regression approach. We conducted a model using the wet deposition of SIAs in a megacity to understand the effects of wet deposition on the SIA concentration using estimated optimal WSCs. The simulated results indicate that washout processes decrease the surface aerosol concentration, showing that reductions in the average surface concentrations from washout processes were from 7.1% to 11.2%. The simulation results suggest that washout processes can reduce the particulate matter concentration in urban areas, indicating that washout processes should be considered in the microscale model, although the modeling domain can only simulate washout processes.
Highlights
Particulate matter (PM) with a diameter of 1 micron or less (PM1) in urban areas is a serious issue because of its negative effects on the human respiratory system and the reduction of atmospheric visibility [1]
Wet deposition processes should be included in the model to examine Secondary inorganic aerosols (SIAs) concentrations properly in urban areas
Our results suggest that washout processes can reduce the PM concentration by up to 11% in the urban area, indicating that washout processes should be considered in the microscale model, the modeling domain can only simulate washout processes
Summary
Particulate matter (PM) with a diameter of 1 micron or less (PM1) in urban areas is a serious issue because of its negative effects on the human respiratory system and the reduction of atmospheric visibility [1]. Wet deposition processes are essential for understanding the fate of SIAs. The computational fluid dynamics (CFD) model is widely used to examine pollutant concentrations in urban areas because it can simulate turbulence from the complex structures of buildings and the dispersion of pollutants following the turbulence. No study has considered wet deposition processes in CFD modeling due to the limitations in fine-scale modeling. Global- and regional-scale chemical transport models include wet deposition processes to determine the SIA level [3,16]. Wet deposition processes should be included in the model to examine SIA concentrations properly in urban areas. The CFD model calculates aerosol concentrations using a chemical aerosol oxidation scheme and a thermodynamic equilibrium model. The detailed model structure typically follows the work by Kim et al [15]
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