Abstract
The Global Change Observation Mission-Climate (GCOM-C) is currently the only satellite sensor providing aerosol optical thickness (AOT) in the ultraviolet (UV) region during the morning overpass time. The observations in the UV region are important to detect the presence of absorbing aerosols in the atmosphere. The recently available GCOM-C dataset of AOT at 380 nm for January to September 2019 were evaluated using ground-based SKYNET sky radiometer measurements at Chiba, Japan (35.62° N, 140.10° E) and Phimai, central Thailand (15.18° N, 102.56° E), representing urban and rural sites, respectively. AOT retrieved from sky radiometer observations in Chiba and Phimai was compared with coincident AERONET and multi-axis differential optical absorption spectroscopy (MAX-DOAS) AOT values, respectively. Under clear sky conditions, the datasets showed good agreement. The sky radiometer and GCOM-C AOT values showed a positive correlation (R) of ~0.73 for both sites, and agreement between the datasets was mostly within ±0.2 (the number of coincident points at both sites was less than 50 for the coincidence criterion of ≤30 km). At Chiba, greater differences in the AOT values were primarily related to cloud screening in the datasets. The mean bias error (MBE) (GCOM-C – sky radiometer) for the Chiba site was −0.02 for a coincidence criterion of ≤10 km. For a similar coincidence criterion, the MBE values were higher for observations at the Phimai site. This difference was potentially related to the strong influence of biomass burning during the dry season (Jan–Apr). The diurnal variations in AOT, inferred from the combination of GCOM-C and ozone monitoring instrument (OMI) observations, showed good agreement with the sky radiometer data, despite the differences in the absolute AOT values. Over Phimai, the AOT diurnal variations from the satellite and sky radiometer observations were different, likely due to the large differences in the AOT values during the dry season.
Highlights
Atmospheric aerosols play a crucial role in controlling Earth’s radiation budget and impact regional climates and hydrological cycles
The newly available Global Change Observation Mission-Climate (GCOM-C) aerosol optical thickness (AOT) at 380 nm was evaluated using sky radiometer observations at the SKYNET Chiba and Phimai sites
The difference in the overpass time of GCOM-C and ozone monitoring instrument (OMI) was utilized to study the diurnal variations in the AOT at 380 nm
Summary
Atmospheric aerosols play a crucial role in controlling Earth’s radiation budget and impact regional climates and hydrological cycles. High near-surface concentrations of aerosol particles impact air quality and human health [1,2]. Global characterization of aerosols (and their effects on the climate) is difficult due to large spatial and temporal variability in their abundance and properties [3]. Satellite observations of aerosols are useful for understanding the large variability of aerosols in space and time [4,5,6]. Large uncertainties occur in satellite aerosol products due to approximations and assumptions in the retrieval process [2]. Ground-based observations under the different surface and atmospheric conditions are required to evaluate the uncertainties in satellite aerosol parameters
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