Abstract
Because of the increased temporal and spatial resolutions of the sensors onboard recently launched satellites, satellite-based surface aerosol concentration, which is usually estimated from the aerosol optical depth (AOD), is expected to become a strategic tool for air quality studies in the future. By further exploring the relationships of aerosol concentrations and their optical properties using ground observations, the accuracies of these products can be improved. Here, we analyzed collocated observations of surface mass concentrations of fine particulate matter (PM2.5) and black carbon (BC), as well as columnar aerosol optical properties from a sky radiometer and aerosol extinction profiles obtained by multi-axis differential optical absorption spectroscopy (MAX-DOAS), during the 2019–2020 period. We focused the analyses on a daily scale, emphasizing the role of the ultraviolet (UV) spectral region. Generally, the correlation between the AOD of the fine fraction (i.e., fAOD) and the PM2.5 surface concentration was moderately strong, regardless of considerations of boundary layer humidity and altitude. In contrast, the fAOD of the partial column below 1 km, which was obtained by combining sky radiometer and MAX-DOAS retrievals, better reproduced the variability of the PM2.5 and resulted in a linear relationship. In the same manner, we demonstrated that the absorption AOD of the fine fraction (fAAOD) of the partial column was related to the variability of the BC concentration. Analogous analyses based on aerosol products from the Modern-Era Retrospective analysis for Research and Applications, Version 2 (MERRA-2) confirmed these findings and highlighted the importance of the shape of the aerosol profile. Overall, our results indicated a remarkable consistency among the retrieved datasets, and between the datasets and MERRA-2 products. These results confirmed the well-known sensitivity to aerosol absorption in the UV spectral region; they also highlighted the efficacy of combined MAX-DOAS and sky radiometer observations.
Highlights
Aerosol particles influence the climate by the direct reflection of solar radiation, as well as indirect enhancement of cloud reflectivity through their role as cloud condensation nuclei
We conducted our observations in an urban environment within the most populous metropolitan area worldwide and local emissions drive the variability in surface aerosol mass concentrations, Figure 1 suggests a meteorological modulation of the aerosol concentrations measured at Chiba University station
This study evaluated the consistencies of observations of surface aerosol concentrations and their associated aerosol optical properties, as estimated by sky radiometer and MAX-DOAS observations recorded at Chiba University (Japan) from November 2019 to December 2020
Summary
Aerosol particles influence the climate by the direct reflection of solar radiation, as well as indirect enhancement of cloud reflectivity through their role as cloud condensation nuclei. While radiation scattering by particles causes an overall atmospheric cooling and negative radiative forcing, light-absorbing particles will warm the atmosphere and potentially cause a positive radiative forcing. 2021, 13, 3163 light-absorbing particles lower the albedo, increase the absorption of solar radiation, and trigger various feedback mechanisms [2]. PM2.5 concentrations are usually measured by ground-based instruments belonging to national/municipal surface monitoring networks. There are far fewer instruments located outside of urban areas, which makes it challenging to extrapolate monitoring network observations over large regions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
