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Validation of SCIAMACHY’s reflectance and polarisation measurements

This study aims to validate the reflectance and polarisation measurements of SCIAMACHY by comparing them with a radiative transfer model. The results show potential calibration offsets and polarisation sensitivity issues, as well as variability in the surface albedo. Further investigation is needed to understand these discrepancies.

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Validation of SCIAMACHY’s reflectance and polarisation measurements

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  1. Validation of SCIAMACHY’s reflectance and polarisation measurements Juan Acarreta, Martin de Graaf, Gijs Tilstra, Piet Stammes (KNMI, De Bilt, NL), Matthijs Krijger (SRON, Utrecht, NL)

  2. Overview of talk • Introduction and approach • Selected SCIAMACHY nadir state • Comparison SCIA vs. model reflectance in 300-400 and 400-800 nm ranges • Effect of UV calibration on AAI • Conclusions

  3. Introduction • R. Siddans et al. (RAL) have found a radiometric calibration offset of the SCIAMACHY nadir reflectances in the UV (320-390 nm cluster) by comparison with GOME, amounting to about –20 %. • Is this due to the polarisation sensitivity of SCIAMACHY and/or to another calibration problem? • NOTE: reflectance (or: reflectivity) R =   radiance / (0  solar irradiance)

  4. Approach • For cloudfree scenes with small aerosol loadings the reflectance and polarisation at TOA can be predicted quite accurately using a radiative transfer model, given the spectral albedo of the surface. Especially in the UV, where most surfaces are dark. • We use the polarised Doubling-Adding KNMI (DAK) model. • The spectral surface albedo is taken from the database of Koelemeijer et al. (JGR, 2002, in press), based on GOME data for 1995-2000. This database contains the Lambertian equivalent reflectivity of the surface at 11 wavelengths between 335 and 772 nm, at a spatial resolution of 1°x1°.

  5. Sketch of the situation sun SCIAMACHY O3 absorption Rayleigh scattering no clouds no aerosols Sahara surface albedo

  6. Selected orbit: 2509 (from verif. database)

  7. MODIS image

  8. SeaWifs image + selected state (no. 11)

  9. Four selected areas of 60 x 280 km²(per area 7 pixels along track)4 (West) 3 (CenterW) 2 (CenterE) 1 (East)

  10. SCIA’s solar irradiance spectrum (ch.1-6)

  11. SCIA’s earth reflectance spectrum (ch.1-6)

  12. SCIAMACHY – DAK comparison Input parameters for DAK: • Surface pressure from meteorological observations • Ozone column from the GOME fast delivery product • Surface albedo from GOME LER database (1995-2000) • Sun-viewing geometry from level 1b data product Output: Reflectance (I/0E), Q/I, and U/I

  13. DAK spectrum 300-800 nmof R (‘’I”), Q/I and U/IEast pixelWest pixel

  14. SCIAMACHY – DAK comparison • Comparison for 320-390 nm (cluster 9), with polarisation correction off. • Comparison with calculated polarisation effect, using instrumental sensitivity and calculated Q and U. • Comparison for 300-800 nm range (clusters 10, 9,15, 17, 24, 26), with polarisation correction on/off.

  15. Pixel 1 (East) – SCIA vs. DAK

  16. Relative difference

  17. Pixel 2 (CenterEast) – SCIA vs. DAK

  18. Relative difference

  19. Pixel 3 (CenterWest) – SCIA vs. DAK

  20. Relative difference

  21. Pixel 4 (West) – SCIA vs. DAK

  22. Relative difference

  23. SCIA’s polarisation sensitivity for scan mirror position of East pixel

  24. Calculated effect of polarisation – East pixel

  25. Actual relative difference

  26. SCIA’s polarisation sensitivity for scan mirror position of West pixel

  27. Calculated effect of polarisation – West pixel

  28. Actual relative difference

  29. Effect of polarisation correction in SCIAL1Cfor 320-390 nm

  30. Pixel 1 (E) for 300-800 nm

  31. Pixel 2 (CE) for 300-800 nm

  32. Pixel 3 (CW) for 300 – 800 nm

  33. Pixel 4 (W) for 300-800 nm

  34. SCIA’s polarisation sensitivity for scan mirror position of East pixel

  35. Calculated effect of polarisation – East pixel

  36. SCIA’s polarisation sensitivity for scan mirror position of West pixel

  37. Calculated effect of polarisation – West pixel

  38. Conclusions of polarisation correction: Polarisation correction at 320-390 nm: • Polarisation correction goes in the right way for the east pixel. • Polarisation correction does not remove the negative offset of the reflectance spectrum. • Polarisation correction should not have an effect for the west pixel, because light is almost unpolarised there. However, in the product there is a polarisation effect for west pixels. Polarisation correction at longer wavelengths: • Small effect; it cannot explain a large offset.

  39. Effect of level 1 calibration offset on AAI • The Absorbing Aerosol index (TOMS residue method) uses the reflectance pair at 340/380 nm • The AAI is normally in the range 0 (no absorbing aerosol) to 4 (high absorbing aerosol load) • A negative offset in the reflectance will affect the AAI: less reflectance means a higher AAI

  40. Correlation betweenLevel 2and own AAI

  41. Correlation betweenLevel 2and own AAI

  42. Conclusions • Comparison of the clear sky TOA reflectance measured by SCIA with a polarised model, shows that SCIA has a UV polarisation correction problem for west pixels and an offset of around –20 % for all pixels. • At the longer wavelengths the surface albedo of the Sahara is dominating the TOA reflectance. This albedo may be variable. It is not clear what the offset is there. • There are some strange spikes in the reflectance.

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