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The Physics of Atmospheric Gas Measurements 2. Atmospheric physics as applied to data analysis algorithms. Kelly Chance Harvard-Smithsonian Center for Astrophysics.
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The Physics of Atmospheric Gas Measurements2. Atmospheric physics as applied to data analysis algorithms Kelly Chance Harvard-Smithsonian Center for Astrophysics
The Horiba Jobin Yvon Company has an excellent website giving a tutorial on the optics of spectroscopy: http://www.horiba.com/us/en/scientific/products/optics-tutorial/
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Ring effect correction spectrum (a) Fraunhofer reference spectrum for the NO2 fitting region; (b) Fraunhofer convolved to GOME spectral resolution; (c) = (b) convolved with rotational Raman cross-sections = Ring effect scattering source per molecule; (d) High-pass filtered version of (c) / (b) = DOAS “Ring effect correction.”
Top-of-atmosphere solar spectral irradiance • The high resolution solar spectral irradiance is critical in analyzing atmospheric trace gases: • Solar lines are source of accurate wavelength calibration (0.0003-0.0004 nm for GOME!) • Determination of the Ring effect • Improved knowledge of instrument slit functions • Correction for spectral undersampling • Photochemistry of Schumann-Runge system • A space-based determination would be an ideal support mission for 12+ international atmospheric missions! • Range: 240-1000+ nm • FWHM: 0.01 nm or better • Ideal FTS Space Shuttle experiment
Griffiths and De Haseth, Fourier Transform Infrared Spectroscopy
Sampling Contributions to Instrument Line Shape (Slit Function) The fully (Nyquist) sampled part is and max is the spatial sampling on the detector. where m runs over the detector pixels. The undersampled part is Chance, K., T.P. Kurosu, and C.E. Sioris, Undersampling correction for array-detector based satellite spectrometers, Applied Optics 44, 1296-1304, 2005.
OMI NO2 window: 2.98 pixel/FWHM OMI instrument transfer function for the NO2 fitting region and the Nyquist-sampled and undersampled portions.
OMI instrument transfer function for the NO2 fitting region and the Nyquist-sampled and undersampled portions for the hypothetical case where the slit function is sampled to twice the spatial frequency.
Undersampling corrections are made by: • Convolving the high resolution solar reference spectrum with the instrument line shape • Resampling this convolved high-resolution to the wavelength-shifted position (the shift between the radiance and irradiance) in two ways: • Properly sampled (using the entire available solar reference spectrum) • Undersampled (using a representation at the actual instrument sampling) • The difference between A and B is the undersampling correction. • Now used in GOME, GOME-2, SCIAMACHY, and OMI
Spectral Undersampling Correction Chance, K. Analysis of BrO measurements from the Global Ozone Monitoring Experiment. Geophys. Res. Lett. 25, 3335-3338, 1998. Slijkhuis, S., A. von Bargen, W. Thomas, and K. Chance, Calculation of undersampling correction spectra for DOAS spectral fitting, Proc. ESAMS'99 - European Symposium on Atmospheric Measurements from Space, 563-569, 1999. Chance, K., T.P. Kurosu, and C.E. Sioris, Undersampling correction for array-detector based satellite spectrometers, Applied Optics 44, 1296-1304, 2005. Solar Reference Spectrum: Chance, K.V., and R.J.D. Spurr, Ring effect studies: Rayleigh scattering, including molecular parameters for rotational Raman scattering, and the Fraunhofer spectrum, AppliedOptics 36, 5224-5230, 1997.
Rayleigh Scattering Phase Function Er E El Petty, 2004
GOME BrO fitting: Relative contributions absorption by atmospheric BrO (top) and the Ring effect - the inelastic, mostly rotational Raman, part of the Rayleigh scattering – (bottom).
Size Parameter x Determines Type of Scattering a = particle radius Petty, 2004