Comparisons of spectral aerosol single scattering albedo in Seoul, South Korea
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Published:2018-04-23
Issue:4
Volume:11
Page:2295-2311
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ISSN:1867-8548
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Container-title:Atmospheric Measurement Techniques
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language:en
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Short-container-title:Atmos. Meas. Tech.
Author:
Mok JungbinORCID, Krotkov Nickolay A.ORCID, Torres Omar, Jethva Hiren, Li ZhanqingORCID, Kim JhoonORCID, Koo Ja-Ho, Go Sujung, Irie Hitoshi, Labow Gordon, Eck Thomas F., Holben Brent N.ORCID, Herman JayORCID, Loughman Robert P., Spinei Elena, Lee Seoung SooORCID, Khatri Pradeep, Campanelli Monica
Abstract
Abstract. Quantifying aerosol absorption at ultraviolet (UV)
wavelengths is important for monitoring air pollution and aerosol amounts
using current (e.g., Aura/OMI) and future (e.g., TROPOMI, TEMPO, GEMS, and
Sentinel-4) satellite measurements. Measurements of column average
atmospheric aerosol single scattering albedo (SSA) are performed on the
ground by the NASA AERONET in the visible (VIS) and near-infrared (NIR)
wavelengths and in the UV-VIS-NIR by the SKYNET networks. Previous
comparison studies have focused on VIS and NIR wavelengths due to the lack
of co-incident measurements of aerosol and gaseous absorption properties in
the UV. This study compares the SKYNET-retrieved SSA in the UV with the SSA
derived from a combination of AERONET, MFRSR, and Pandora (AMP) retrievals
in Seoul, South Korea, in spring and summer 2016. The results show that
the spectrally invariant surface albedo assumed in the SKYNET SSA retrievals
leads to underestimated SSA compared to AMP values at near UV wavelengths.
Re-processed SKYNET inversions using spectrally varying surface albedo,
consistent with the AERONET retrieval improve agreement with AMP SSA. The
combined AMP inversions allow for separating aerosol and gaseous (NO2
and O3) absorption and provide aerosol retrievals from the shortest
UVB (305 nm) through VIS to NIR wavelengths (870 nm).
Publisher
Copernicus GmbH
Subject
Atmospheric Science
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