Cloud algorithms and applications for TEMPO Joanna Joiner, Alexander Vasilkov, Nick Krotkov, Sergey Marchenko, Eun-Su Yang, Sunny Choi (NASA GSFC)
Dec 28, 2015
Cloud algorithms and applications for TEMPO
Joanna Joiner, Alexander Vasilkov, Nick Krotkov, Sergey Marchenko,
Eun-Su Yang, Sunny Choi (NASA GSFC)
TEMPO Clouds: cloud optical centroid pressure and effective cloud fraction
• Default baseline algorithm: OMI rotational-Raman algorithm (CLDRR)– Fitting window currently 346-354 nm – Mixed-Lambertian cloud model– Validated with CloudSat, O2-O2 intercomparisons– shown to improve O3 and SO2 retrievals– Requires lookup table to be generated using a solar irradiance spectrum– Soft calibration improves retrievals (striping) for OMI/OMPS, use data over
Antarctica (will not have this luxury for TEMPO!)– Sensitive to spectral errors (e.g., OMPS solar diffusor features and undersampling
are issues; for OMI straylight an issue; solar variations a possible issue, currently not accounted for))
– Applied to OMPS (Vasilkov et al., 2014, AMT); required changes to OMI code (spline interpolation; use of synthetic solar spectrum to generate tables)
– Some difference seen between OMI and OMPS that are currently not understood– Added simple error estimates, errors go as 1/fr
TEMPO clouds: other options
• O2-O2 (~477 nm) – Implemented by KNMI for OMI,– ~P2 dependence, weak band (~1% signal)– Validated with CloudSat, OMCLDRR intercomparisons– New visible fitting at GSFC also fits this band, minor
differences with KNMI fitting– Potential backup cloud algorithm for TEMPO– Currently implementing, testing F90 version, very fast,
currently uses same surface reflectivity as KNMI, uses climatological temperature profiles (important!)
Tall poles for CLDRR applied to TEMPO
• Soft-calibration– Significant striping seen in OMI (could be an issue
for any cloud algorithm from similar instruments)– How do we apply soft calibration for TEMPO?
• Using data over land did not work well for OMI (surface BRDF effects an issue?)
• use cloud climatology from OMI; identify areas of low cloud pressure variability (e.g., low marine clouds)?
• posterior correction to cloud OCPs?
Backups
First Global Free Tropospheric NO2 Concentrations Derived Using a Cloud Slicing Technique Applied to Satellite Observations from the Aura Ozone Monitoring Instrument (OMI)
S. Choi1,2, J. Joiner2, Y. Choi3, B. N. Duncan2, E. Bucsela4 (Currently in AMTD)1Science Systems and Applications, Inc. (SSAI), 2NASA Goddard Space Flight Center, 3University of Houston, 4SRI Interntaional
NASA GSFC Laboratory for Atmospheric Chemistry and Dynamics
These global maps show 3-month seasonal averages of free tropospheric NO2 mixing ratio (gridded at 6o latitude x 8o longitude resolution) for Dec-Feb (top panel) and Jun-Aug (bottom panel) 2005-2007. These maps show clear signatures of anthropogenic contributions near densely populated regions as well as lightning contributions over tropical oceans.
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Comparison of OMPS and OMIOMPS
OMI
Cloud pressure retrievals of Jan 07, 2013 (ECF>0.05)
• Most cloud OCP patterns are same (northern Pacific, Mexico, northern Atlantic, northern China)
• OMI OCP retrievals are somewhat lower than OMPS particularly in the tropics
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Comparison of PDFs of cloud pressure, OMI O2-O2 added
Southern mid-latitudes Tropics Northern mid-latitudes
Differences between OMI RRS and OMPS cloud pressures appear to be similar to differences between OMI RRS and OMI O2-O2
except for the differences in the tropics.