Determining diurnal variations of land surface emissivity from geostationary satellites

Infrared (IR) land surface emissivity (LSE) with a high temporal and spatial resolution is very important for deriving other products using IR radiance measurements as well as assimilating IR radiances in numerical weather prediction (NWP) models over land. Retrieved from various satellite instrumen...

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Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres 2012-12, Vol.117 (D23), p.n/a
Main Authors: Li, Zhenglong, Li, Jun, Li, Yue, Zhang, Yong, Schmit, Timothy J., Zhou, Lihang, Goldberg, Mitchell D., Menzel, W. Paul
Format: Article
Language:English
Subjects:
Algorithms
Atmospheric sciences
diurnal change
diurnal variation
Diurnal variations
Earth sciences
Earth, ocean, space
Emissivity
Exact sciences and technology
External geophysics
Geophysics
High performance computing
land surface emissivity
Land surface temperature
Mesoclimatology
Moisture content
Moisture profiles
Planetology
Planets
Remote sensing
Sandy soils
satellite
SEVIRI
Soil moisture
Soil surfaces
Weather forecasting
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Summary:Infrared (IR) land surface emissivity (LSE) with a high temporal and spatial resolution is very important for deriving other products using IR radiance measurements as well as assimilating IR radiances in numerical weather prediction (NWP) models over land. Retrieved from various satellite instruments, many LSE databases are available for operational and research use. Most are updated only monthly; assuming emissivity does not change within the month. However, laboratory measurements have shown that emissivity increases by 1.7% to 16% when soil moisture content becomes higher, especially in sandy soils in the 8.2–9.2 μm range. And a clearly defined wave‐like diurnal pattern of decreasing surface soil moisture during the day and recovery (or increased soil moisture) at night was observed. Therefore, it is expected that LSE possesses a diurnal wave‐pattern variation with low values during day time and high values during nighttime. The physically based GOES‐R ABI LSE algorithm uniquely exploits the geostationary satellites' high temporal resolution. The algorithm was developed and applied to the radiance measurements from the Spinning Enhanced Visible and InfraRed Imager (SEVIRI) on the Meteosat Second Generation (MSG) Meteosat‐8/9. The results over the Sahara Desert show that 8.7μm emissivity has a significant diurnal wave‐pattern variation, with high values during nighttime and low values during day time. 10.8μm emissivity also shows a similar diurnal variation, but with a smaller amplitude compared to 8.7 μm. 12.0 μm emissivity has an even weaker diurnal variation, and an opposite pattern as 8.7 and 10.8 μm. Evidence is provided to demonstrate that the SEVIRI LSE diurnal wave‐pattern variations are real, not artifacts from the retrieval algorithm. The impacts of diurnal variations of errors in GFS forecast (temperature and moisture profiles) and in land surface temperature (LST) are analyzed; they are found to be minor compared to the LSE diurnal variations shown by SEVIRI. Key Points The retrieved SEVIRI land surface emissivity shows diurnal variations SEVIRI and MODIS radiance observations confirm the LSE diurnal variations
ISSN:0148-0227
2169-897X
2156-2202
2169-8996
DOI:10.1029/2012JD018279