Abstract
Abstract. Aerosol optical depth (AOD) in the western United States is observed independently by both the (Geostationary Operational Environmental Satellites) GOES-East and GOES-West imagers. The GASP (GOES Aerosol/Smoke Product) aerosol optical depth retrieval algorithm treats each satellite as a unique sensor and thus obtains two separate aerosol optical depth values at the same time for the same location. The TOA (the top of the atmosphere) radiances and the associated derived optical depths can be quite different due to the different viewing geometries with large difference in solar-scattering angles. In order to fully exploit the simultaneous observations and generate consistent AOD retrievals from the two satellites, the authors develop a new "hybrid" aerosol optical depth retrieval algorithm that uses data from both satellites. The algorithm uses both GOES-East and GOES-West visible channel TOA reflectance and daily average AOD from GOES Multi-Angle Implementation of Atmospheric Correction (GOES-MAIAC) on low AOD days (AOD less than 0.3), when diurnal variation of AOD is low, to retrieve surface BRDF (Bidirectional Reflectance Distribution Function). The known BRDF shape is applied on subsequent days to retrieve BRDF and AOD. The algorithm is validated at three AERONET sites over the western US. The AOD retrieval accuracy from the "hybrid" technique using the two satellites is similar to that from one satellite over UCSB (University of California Santa Barbara) and Railroad Valley, Nevada. Improvement of the accuracy is observed at Boulder, Colorado. The correlation coefficients between the GOES AOD and AERONET AOD are in the range of 0.67 to 0.81. More than 74% of AOD retrievals are within the error of ±(0.05 + 0.15 τ) compared to AERONET AOD. The hybrid algorithm has more data coverage compared to the single satellite retrievals over surfaces with high surface reflectance. For single observation areas the number of valid AOD data increases from the use of two-single satellite algorithms by 5–80% for the three sites. With the application of the new algorithm, consistent AOD retrievals and better retrieval coverages can be obtained using the data from the two GOES satellite imagers.
Highlights
Ocean Science daily average Aerosol optical depth (AOD) from GOES Multi-Angle Implementa- Atmospheric aerosol is an important component of clition of Atmospheric Correction (GOES-Multi-Angle Implementation of Atmospheric Correction (MAIAC)) on low mate change and public health research
GOES AOD retrievals within a 5 × 5 box (20 × 20 km2) surrounding the AERONET site are averaged and the two closest AERONET measurements within 15 min before and after the GOES observation are interpolated to the GOES observation time
A new “hybrid” AOD retrieval algorithm was developed over the western US utilizing both GOES-West and GOES-East satellite data
Summary
Ocean Science daily average AOD from GOES Multi-Angle Implementa- Atmospheric aerosol is an important component of clition of Atmospheric Correction (GOES-MAIAC) on low mate change and public health research. AOD days (AOD less than 0.3), when diurnal variation of “force” climate through the direct and several indirect ef-. AOD is low, to retrieve surface BRDF (Bidirectional Re- fects (Charlson et al, 1992; Kiehl and Briegleb, 1993; Raflectance Distribution Function). The known BRDF shape is applied on subsequent days to retrieve BRDF and AOD. The AOD retrieval accuracy from the “hybrid” et al, 2006). Improvement of the accuracy is observed at Boulder, Colorado. The correlation coefficients i(nhgttpn:/e/tawironrokws,.gaovva)i.laTbTolehfiltelothtCheergpyaupobsslbicpetawhteetehrneethAeIRsuNrOfaWce site stations, satellite retrieved aerosol properties such as aerosol
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