We use the fractional aerosol optical depth (AOD) values derived from Multiangle Imaging Spectroradiometer
(MISR) aerosol component measurements, along with aerosol transport model constraints, to estimate ground-level
concentrations of fine particulate matter (PM2.5)mass and its major constituents in the continental United
States. Regression models using fractional AODs predict PM2.5 mass and sulfate (SO4) concentrations in both the
eastern and western United States, and nitrate (NO3) concentrations in the western United States reasonably well,
compared with the available ground-level U.S. Environment Protection Agency (EPA) measurements. These models show substantially improved predictive power when compared with similar models using total-column AOD as a single predictor, especially in the western United States. The relative contributions of the MISR aerosol components in these regression models are used to estimate size distributions of EPA PM2.5 species. This
method captures the overall shapes of the size distributions of PM2.5 mass and SO4 particles in the east and west, and NO3 particles in the west. However, the estimated PM2.5 and SO4 mode diameters are smaller than those previously reported by monitoring studies conducted at ground level. This is likely due to the satellite sampling bias caused by the inability to retrieve aerosols through cloud cover, and the impact of particle hygroscopicity on measured particle size distributions at ground level.