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Applications and Limitations of Satellite Data

Applications and Limitations of Satellite Data. Professor Ming-Dah Chou January 3, 2005 Department of Atmospheric Sciences National Taiwan University. Why Satellite Observation?. Other than cloud images, why do we need satellite data for regional weather and climate studies in Taiwan?.

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Applications and Limitations of Satellite Data

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  1. Applications and Limitations of Satellite Data Professor Ming-Dah Chou January 3, 2005 Department of Atmospheric Sciences National Taiwan University

  2. Why Satellite Observation? • Other than cloud images, why do we need satellite data for regional weather and climate studies in Taiwan?

  3. A short answer is… • For extended weather and climate forecasts, large-scale circulations and physical environment (e.g. SST, snow/ice cover) become very important. Large-scale circulations and physical environment can be best observed from satellite.?

  4. Some Examples for Application of Satellite Data • Model Initialization/Assimilation/Reanalysis • Validation • Improvements on model physics

  5. Model:Initialization/ Assimilation/Reanalysis • Initialization for weather forecast • Assimilation • Reanalysis (model + satellite observation) Accurate and long-term Description of the earth-atmosphere system.

  6. Validation of weather forecast and climate simulations • What parameters? • Diagnostic • Prognostic • Clouds • Radiative heat budgets • Cloud radiative forcing • Temperature • Humidity • SST • Ice and snow cover • Others

  7. Model improvement • Interaction between dynamical and physical processes (intra-seasonal and inter-annual variations) • Tropical disturbances and air-sea interaction (momentum and heat fluxes) • Interaction between monsoon dynamics, precipitation, and radiation.

  8. Satellite Retrievals • Solar Spectral Channels • Thermal Infrared Channels • Microwave Channels

  9. Solar Spectral Channels • Measurement of reflection at narrow channels • Lack of vertical information

  10. Information Derived • Clouds • Aerosols • Fractional cover (visible channel) • Article size (multiple channels) • Cloud water amount (multiple channels) • Cloud contamination problem especially thin cirrus clouds. • Mostly over oceans. • Large uncertainty over land especially over deserts • Optical thickness; spectral variation (multiple channels) • Single scattering albedo (large uncertainty) • Asymmetry factor (large uncertainty)

  11. Information Derived (Continued) • Ozone • Land reflectivity • Vegetation cover • Ice/snow cover • Total ozone amount (multiple channels) • Spectral variation • NDVI (Normalized Difference Vegetation Index); • Reflection (albedo) difference of two channels • Sudden albedo jump across green light • Cloud contamination problem • Multiple channels to differentiate clouds and ice/

  12. Thermal Infrared Channels • Rationale: emission and absorption of thermal IR

  13. Information Derived • Temperature profile • Water vapor profile • Multiple channels in the CO2 absorption band • Uniform CO2 concentration • Weighting functions peak at different heights • Multiple channels in the H2O absorption band • Coupled with temperature retrievals • Low vertical resolution • Broad weighting function

  14. Information Derived (Continued) • Clouds • Fractional cover • Cloud height • Particle size • Cloud water amount • Cloud-surface temperature contrast • High spatial resolution • Window channel • Opaque clouds in thermal IR • Emission at cloud top • Unreliable • Unreliable

  15. Microwave Channels • Emission and absorption in microwave spectrum • Long wavelength • Capable of penetrating through clouds

  16. Information Derived • Temperature profile • Water vapor profile • Multiple channels in an absorption line • Uniform CO2 concentration • Weighting functions peak at different heights • Multiple channels in a H2O absorption line • Coupled with temperature retrievals • Low vertical resolution • Broad weighting function

  17. Information Derived (Continued) • Precipitation • Multiple channels • Polarization (particle size) • Long wavelength; sensitive to large particles • Vertical distribution of precipitation

  18. SST Retrievals • IR Technique • Microwave Technique

  19. IR Technique • Three IR window channels (3.7, 10, and 11 μm) • Differential water vapor absorption • Regression • Satellite measurements vs buoy measurements • Sub-surface temperature • Clear sky only • NOAA/AVHRR, NASA/MODIS • NOAA NCEP claims SST retrieval accuracy is ~0.2-0.3 C

  20. Microwave Technique • Single microwave channel • Unaffected by clouds and water vapor • Rain (?) • Sub-surface temperature (?)

  21. Microwave Technique (Cont.) ε: estimated from surface wind Ts: SST Tb: Satellite measured brightness temperature For Ts=300 K and ε=0.5, we have Tb=150K and If ∆ε=0.001, ∆Ts=0.6 K……VERY SENSITIVE! • Bias among MODIS-, AVHRR-, and TRMM-derived SST is large, reaching 0.5-1.0 °C

  22. Clouds Retrieval • Day: Use both solar and thermal IR channels • Night: Use only thermal IR channels • High spatial resolution of satellite measurements A field-of-view picture element (pixel) is either totally cloud covered or totally cloud free • Cloud detection: αsat > αth; Tsat < Tth Threshold albedo (αth) and brightness temperature (Tth) are empirically determined

  23. Clouds Retrieval (cont.) • Zonally-averaged cloud cover of NASA/ISCCP, NASA/MODIS, and NOAA/NESDIS could differ by 30-40% • Uncertainties of cloud optical thickness, particle size and water content are even larger than that of cloud cover • Regardless of the large uncertainties of cloud retrievals, global cloud data sets could be useful depending on applications.

  24. Aerosols • Various sources/types of aerosols: Fossil fuel combustions, dust, smoke, sea salt • Large temporal and regional variations • Short life time, ~10 days • Difficult to differentiate between aerosols and thin cirrus • Difficult to retrieve aerosol properties over land • high surface albedo • Differences between various data sets of satellite-retrieved, as well as model-calculated aerosol optical thickness are large. • Impact of aerosols on thermal IR is neglected. • Potentially, aerosols could have a large impact on regional and global climate.

  25. Thin Cirrus CloudsUpper Tropospheric Water Vapor • Climatically very important • Thin cirrus clouds are wide spread, but too thin to be reliably detected • Upper tropospheric water vapor is too small to be reliably retrieved • Thin cirrus clouds: • Upper tropospheric water vapor • Although difficult to retrieve from satellite measurements, there are no other alternatives. • Key to understand feedback mechanisms in climate change studies. • Weak absorption visible channel (0.55 μm) • Strong absorption near-IR channel (1.36 μm) • Strong absorption water vapor channel (6.3 μm)

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