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Exploring the Impact of Sea Surface Temperature and Salinity on SMAP Excess Surface Emissivity
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2024
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Source: IEEE Transactions on Geoscience and Remote Sensing, 62, 1-11
[PDF-17.52 MB]
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Journal Title:IEEE Transactions on Geoscience and Remote Sensing
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Description:The soil moisture active passive (SMAP) instrument has been used to infer sea surface wind speed from its brightness temperature measurements. To do so, the SMAP wind speed retrieval process requires the removal of sea surface temperature (sst) and sea surface salinity (sss) impact on brightness temperature. Estimating the so-called excess surface emissivity ( Δe ), that is the sst normalized difference between the measured brightness temperature of the sea surface and the corresponding brightness temperature of a flat surface, is one way of accomplishing such a task. In this article, we investigate whether SMAP Δe contains residual dependencies to sst and sss. To do so, v5.0 SMAP brightness temperature measurements, derived by the Jet Propulsion Laboratory, are used. For any fixed numerical weather prediction model wind speed above 15 m/s, down to a 20% decrease in SMAP Δe is observed as the sst increases from 274 to 304 K. For any fixed wind speed between 8 and 15 m/s, the sst residual dependence is weaker with SMAP Δe exhibiting a 1%–2% decrease as the sst increases. Below 8 m/s, this pattern becomes prevalent again, when the significant wave height (Hs) is greater than 3.5 m. SMAP Δe decreases as much as 50% with increasing sss, most notably below 8 and above 15 m/s when Hs is considered. This analysis has also shown that below 8 m/s and for swell dominant seas, a decrease in either sss or sst results in a decrease in SMAP Δe sensitivity to wind-induced sea surface roughness.
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Source:IEEE Transactions on Geoscience and Remote Sensing, 62, 1-11
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ISSN:0196-2892;1558-0644;
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Rights Information:CC BY-NC-ND
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