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Now That I Know That… What Do I Do? (Analyzing your Microtop Solar Radiometry Data)

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Presentation on theme: "Now That I Know That… What Do I Do? (Analyzing your Microtop Solar Radiometry Data)"— Presentation transcript:

1 Now That I Know That… What Do I Do? (Analyzing your Microtop Solar Radiometry Data)

2 Review: Transmissivity The probability that a photon will pass through a medium without interacting with it (absorption or scattering) is: where: T = the “transmissivity” of the medium τ = the “optical thickness” of the medium.

3 Review: Optical Thickness Optical thickness τ is the (dimensionless) radiative unit of length where: n = the number of “extincters” (scatterers or absorbers) per unit volume in the medium σ = the extinction cross-section (effective area per “extincter”) s = the geometric path length

4 Linear Problem  Additive τ A medium typically has several kinds of “extincters”, but their effects are additive: where: n a1 = the number of the 1 st absorber per unit volume σ a1 = the absorption cross-section (effective area per absorber) for the 1 st absorber So: (Etc., etc.)

5 Beer’s Law Assume that your measurement consists only of solar radiation that is transmitted through the atmosphere without interacting with it. Then the measured spectral irradiance F can be described by Beer’s Law as: where: F 0 = the spectral solar extraterrestrial irradiance τ s = the “optical path length” of the medium along the solar beam.

6 Geometry Since the sun is not directly overhead, the geometric path length along the solar beam (S) is longer than a line along the zenith to the same altitude (A).

7 Flat Atmosphere? But as long as the sun is not too near the horizon (say, z < 80º), the atmosphere can be treated as “flat,” and S is related to A by a simple cosine law, with 1/cos z called the “air mass factor” m.

8 Putting it all together If we assume that the atmosphere is horizontally homogenous, then m is the only difference between a zenith line of sight and our slant line of sight, and so: where a1 = ozone absorption, s1 = Rayleigh (molecular) scattering, and s2 = Mie (aerosol) scattering

9 So… what did I measure? The only thing the instrument really measures is F at 5 wavelengths: 305, 312, 320, 340 and 380 nm (ozone-sensitive)(aerosol-sensitive) The instrument did some internal calculations to give you more information, however…

10 And the other bits come from…? F 0 = extraterrestrial solar spectral irradiance (from independent measurements) m = air mass factor (from geometry, given your location and the local time) σ a1 = ozone absorption cross-section (from lab measurements) τ s1 = molecular scattering optical depth (using laboratory measured cross-sections, and assuming a standard atmosphere, given your location)

11 So… what else did I get? The instrument therefore also can tell you about: Ozone column amount[ ] (in Dobson units) and Aerosol Optical Depth (no units) [ ] at each wavelength.

12 And a “Dobson Unit” is…? Take all of the ozone in a column above a given point at the surface, and compress it to p = 1 atm, T = 0ºC. The resulting layer of ozone is typically ~ 0.3 cm thick, which corresponds to 0.3 “atm-cm” of ozone, or 300 “Dobson units.”

13 Why do I get several ozone estimates? The ozone estimate is made by comparing the differential absorption between 2 adjacent wavelengths whose sensitivity to ozone differs significantly. Each different estimate uses a different pair of wavelengths. If ozone is abundant, the weakly absorbed wavelengths will give a better ozone estimate; if ozone is scarce, the strongly absorbed wavelengths will give a better estimate.

14 Ozone Cross-Section σ a1

15 Aerosol Cross-Section Depends on the nature of the aerosol (size distribution, optical properties, etc.). For typical tropospheric aerosol, the following rule is often useful to estimate the variation over small wavelength intervals: α is the “Angstrom coefficient” for the aerosol, and is typically ~ 1 or 2. Compare to Rayleigh scattering:

16 Final Adjustments Based on the manufacturer’s calibration, you should make the following adjustments prior to using your data: Instrument #5:Instrument #7 Ozone is 1.2% highOzone is 1.0% high 340nm aer is 0.007 high340nm aer is 0.009 high 380nm aer is 0.048 high380nm aer is 0.061 high

17 TEAM 2 Ozone Data from MICROTOPS 7 TEAM 1 Ozone Data from MICROTOPS 5 TEAM 3 AOT Data from MICROTOPS 5 (340 nm, 380 nm) TEAM 4 AOT Data from MICROTOPS 7 (340 nm, 380 nm) Inter-comparison Diurnal Variation Trend Satellite Data Inter-comparison Diurnal Variation Trend Satellite Data OZONE AEROSOLS

18 THE END

19 Team #1 You have 2 month-long datasets. Make ozone and aerosol plots that characterize: The consistency of the two datasets The existence (or not) of diurnal trends in the retrieved quantities The existence (or not) of longer-term trends (weekly? Seasonal?) The relative skill of the various students?

20 Team #2 Make ozone and aerosol plots that characterize: The accuracy of the two instruments, as compared to satellite data (from the OMI instrument) Possible sources of disagreement between ground- based and satellite-based estimates of these quantities

21 Team #3 Use the ozone and aerosol information to calculate the diffuse radiation (as well as the direct radiation). Comment on the relative contributions of diffuse vs direct radiation to the downward irradiance at the various wavelengths

22 Team #4 Use the data to estimate the extraterrestrial solar spectral irradiance at each measured wavelength Compare your results to independent measurements This cross-section data might be useful 305312320340380 Ozone (1/atm- cm) 5.0841.9770.85800 Rayleigh (1/atm) 1.1261.0290.9300.7180.450

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