Abstract
We investigate the effects of aerosol peak height (APH) and various parameters on the air mass factor (AMF) for SO2 retrieval. Increasing aerosol optical depth (AOD) leads to multiple scattering within the planetary boundary layer (PBL) and an increase in PBL SO2 AMF. However, under high AOD conditions, aerosol shielding effects dominate, which causes the PBL SO2 AMF to decrease with increasing AOD. The height of the SO2 layer and the APH are found to significantly influence the PBL SO2 AMF under high AOD conditions. When the SO2 and aerosol layers are of the same height, aerosol multiple scattering occurs dominantly within the PBL, which leads to an increase in the PBL SO2 AMF. When the APH is greater than the SO2 layer height, aerosol shielding effects dominate, which decreases the PBL SO2 AMF. When the SO2 and aerosol layers are of the same height under low AOD and solar zenith angle (SZA) conditions, increased surface reflectance is found to significantly increase the PBL SO2 AMF. However, high AOD dominates the surface reflectance contribution to PBL SO2 AMF. Under high SZA conditions, Rayleigh scattering contributes to a reduction in the light path length and PBL SO2 AMF. For volcanic SO2 AMF, high SZA enhances the light path length within the volcanic SO2 layer, as well as the volcanic SO2 AMF, because of the negligible photon loss by Rayleigh scattering at high altitudes. High aerosol loading and an APH that is greater than the SO2 peak height lead to aerosol shielding effects, which reduce the volcanic SO2 AMF. The SO2 AMF errors are also quantified as a function of uncertainty in the input data of AOD, APH, and surface reflectance. The SO2 AMF sensitivities and error analysis provided here can be used to develop effective error reduction strategies for satellite-based SO2 retrievals.
Highlights
Through the formation of gas-phase sulfuric acid and sulfate aerosol, sulfur dioxide (SO2) plays an important role in atmospheric chemistry on a global scale and affects short-term pollution as well as climate forcing [1,2]
The aim of this study is to investigate the simultaneous effects of aerosol peak height (APH), aerosol optical depth (AOD), geometric information, SO2 vertical profile (PBL vs. volcanic), ozone amount, ozone vertical profile, and surface reflectance on both planetary boundary layer (PBL) and volcanic SO2 air mass factor (AMF)
The PBL SO2 AMF error budget was calculated on the basis of the uncertainties associated with the APH, AOD, and surface reflectance because we found that the SO2 AMF errors were caused mainly by the APH, AOD, and surface reflectance rather than the measurement geometries and ozone profile
Summary
Through the formation of gas-phase sulfuric acid and sulfate aerosol, sulfur dioxide (SO2) plays an important role in atmospheric chemistry on a global scale and affects short-term pollution as well as climate forcing [1,2]. The differential optical absorption spectroscopy (DOAS) spectral fitting method has been widely used to retrieve SO2 column amounts from radiance data measured by these hyperspectral satellite sensors [2,5,6,7,9,10,11,17,18,19,20,21,22,23] Spectral fitting methods such as the DOAS or Principal Component Analysis (PCA) techniques are first used to retrieve the SO2 slant column density (SCD), which is the integral part of the SO2 concentration that is present over the path between a light source and the sensor [24]. Lee et al [26] carried out a PBL SO2 AMF error analysis for surface reflectance, aerosol properties, cloud fraction, and SO2 vertical distribution
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