AI Article Synopsis
- Brown carbon (BrC) aerosols play a significant role in warming Earth's atmosphere, but their light-absorption properties in the Asian outflow region are not well understood.
- This study, conducted on Fukue Island in Japan, used filter measurements and remote sensing to analyze BrC's light-absorption coefficient, finding a correlation with black carbon (BC) due to shared combustion sources.
- The research identified a high-BrC event linked to air masses from fossil fuel combustion and biomass burning in East China, aiding in understanding the climatic impacts of BrC aerosols in East Asia.
Article Abstract
Brown carbon (BrC) aerosols have important warming effects on Earth's radiative forcing. However, information on the evolution of the light-absorption properties of BrC aerosols in the Asian outflow region is limited. In this study, we evaluated the light-absorption properties of BrC using in-situ filter measurements and sky radiometer observations of the ground-based remote sensing network SKYradiometer NETwork (SKYNET) made on Fukue Island, western Japan in 2018. The light-absorption coefficient of BrC obtained from filter measurements had a temporal trend similar to that of the ambient concentration of black carbon (BC), indicating that BrC and BC have common combustion sources. The absorption Angstrom exponent in the wavelength range of 340-870 nm derived from the SKYNET observations was 15% higher in spring (1.81 ± 0.30) than through the whole year (1.53 ± 0.50), suggesting that the Asian outflow carries light-absorbing aerosols to Fukue Island and the western North Pacific. After eliminating the contributions of BC, the absorption Angstrom exponent of BrC alone obtained from filter observations had a positive Spearman correlation (r = 0.77, p < 0.1) with that derived from SKYNET observations but 33% higher values, indicating that the light-absorption properties of BrC were successfully captured using the two methods. Using the atmospheric transport model FLEXPART and fire hotspots obtained from the Visible Infrared Imaging Radiometer Suite product, we identified a high-BrC event related to an air mass originating from regions with consistent fossil fuel combustion and sporadic open biomass burning in central East China. The results of the study may help to clarify the dynamics and climatic effects of BrC aerosols in East Asia.
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| http://dx.doi.org/10.1016/j.scitotenv.2021.149155 | DOI Listing |
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