According to [2], the measurements from which the cooling rate profile is inverted are a function of channel radiance measurements taken at viewing angle.

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Presentation transcript:

According to [2], the measurements from which the cooling rate profile is inverted are a function of channel radiance measurements taken at viewing angle and the mean band radiance taken at a viewing angle (around 45º from nadir). The weighting function is defined by the first 3 terms (density profile, heat capacity, and channel transmittance, respectively) of the integrand of the left- hand side of the above equation. The weighting terms and are determined empirically. The first term on the right-hand side is proportional to the TOA band flux while the second term indicates the particular channel’s spectral cooling rate contribution to the total band cooling. The inversion of the measurement y is performed through a linear Bayesian update 9 to the a priori cooling rate profile. We adhere the notation in [9] to describe retrieval quantities: The a priori covariance matrix S a is created according to a differential analysis of the temperature dependence of the cooling rate profile. The measurement covariance matrix S ε is created by multiplying channel noise-effective radiance by the weighting terms and. We explore the concept of a retrieval of the thermal infrared cooling rate profile using top-of- atmosphere spectral radiance measurements and demonstrate that the retrieval of this quantity can be performed directly 1, 2. Our approach has specific advantageous in terms of accuracy and computational speed, as compared to the conventional indirect approach using the retrieved atmospheric state vector coupled with a band-model calculation of the cooling rate profile. As a test case, we carried out a retrieval in the strong cooling band associated with the 15 μm band of CO 2 employing the Top-of-Atmosphere (TOA) spectra of the Atmospheric Infrared Sounder (AIRS, 2002-present) 3 on board the Aqua satellite, along with validation campaign data and under-flight Scanning High-Resolution Interferometer (S-HIS) zenith and nadir spectra taken aboard a high-altitude aircraft 4. Also, retrieval sensitivity analyses have been performed for the AIRS instrument. Preliminary study of the Infrared Interferometer Sounder (IRIS-D) 5 data is also discussed. It is anticipated that the large changes in cooling rate profile of the 15 μm between the two missions would lead to detectable changes in the CO 2 radiative forcing at the tropopause so long as the IRIS-D instrument can be appropriately characterized. Abstract Direct Retrieval of Radiative Flux-Divergence and Radiative Forcing from Satellite Spectral Measurements D.R. Feldman †, K.N. Liou, Y.L. Yung, D.C. Tobin, A. Berk Department of Environmental Science and Engineering, California Institute of Technology 1.Feldman, D. R., K.N. Liou, et al. (submitted). Geophysical Research Letters (2005GL02468). 2.Liou, K. N. and Y. K. Xue (1988). Meteorology and Atmospheric Physics 38(3): Aumann, H. H., M. T. Chahine, et al. (2003). IEEE Transactions on Geoscience and Remote Sensing 41(2): Revercomb, H. (1998). ( ) ASSFTS Conference, Toulouse, France. 5.Hanel, R. A., Salomons.Vv, et al. (1972). Journal of Geophysical Research 77(15): Anderson, G.P., et al. (1986) AFGL Atmospheric Constituent Profiles (0-120km), AFGL-TR Mlawer, E. J., S. J. Taubman, et al. (1997). Journal of Geophysical Research-Atmospheres 102(D14): ECMWF 40 Years Reanalysis, monthly means ( ). 9.Rodgers, C. D. (2000). Inverse Methods for Atmospheric Sounding: Theory and Practice. London, World Scientific. 10.AVE (2005). AURA Validation Data Center ( ). Greenbelt, MD, NASA. 11.Harrington, J. and J. Verlinde (2004). ( )The Pennsylvania State University: IPCC, Climate Change 2001: Working Group I: The Scientific Basis ( ). 13.Durre, I., R. S. Vose, and D. B. Wuertz (accepted) : Journal of Climate, ( ). References: Computational Expense: Retrieval Setup: Research supported by NASA Earth Systems Science Fellowship, NASA grant NNG04GD76G, and the AIRS Project at JPL. A.Berk’s collaboration was supported by AFRL/BAA FA C † Corresponding Author Contact Information: 1200 E. California Blvd. MC ; Pasadena, CA USA; 15 µm Cooling Rate Profile Variability: Introduction: The infrared cooling rate profile is dependent upon individual layer atmospheric state vector values and their relationship to the broad structure of the atmospheric state, we seek to understand whether high-resolution infrared spectra can offer a better description of the infrared cooling rate profile beyond the atmospheric state standard products, especially in polar regions. Therefore, the retrieval must analyze absorption band channels in the context of a channel’s description of the radiative cooling of that band at a certain level as opposed to a channel’s description of an atmospheric state quantity at that level. Figure 1: Spectral cumulative cooling rate contribution function for mid-latitude summer conditions 6. Values in excess of unity are allowed for levels where spectral heating occurs. The cooling rate profile is proportional to the net radiative flux divergence in a spectral interval. The total clear-sky IR cooling rate profile is determined by strong radiators including H 2 O, CO 2, O 3, and CH 4. Spectral Cooling Rate Profile Definition: Spectral Cumulative Cooling Rate Contribution Function a b Figure 2: Meridional profile of (a) mean zonal and (b) mean monthly temporal variability of cooling rate from cm -1 calculated with RRTM 7 using ERA-40 T, H 2 O, and O 3 fields for Conventional Approach Cooling Rate Retrieval N * ΔT + CLR(M+1) * ΔT ΔT: time for radiative transfer calculation CLR: time for cooling rate calculation N: # model layers M: # cross-track scan angles used Computational Comparison Figure 3: Normalized weighting functions for (a) cooling rate profile retrieval and (b) temperature profile retrieval for mid-latitude summer conditions with the AIRS instrument. a b Weighting Functions: 1)Cooling rate retrievals represent a novel utilization of cross-track-scanning radiance data to offer the prospect of retrieving cooling rate profiles by bypassing standard atmospheric state retrievals and subsequent cooling rate calculations. There is a computational advantage and weighting functions for the same channel peak higher in the atmosphere. 2)Cross-comparison of calculated cooling rate profiles from AVE and MPACE with AIRS retrieved cooling rate profiles in the 15 µm band lend confidence to our methods. 3)Changes in the 15 µm band cooling rate profile in between 1970 and present may be detectable using IRIS-D spectra in conjunction with IGRA RAOBs and current satellite IR spectrometers. Conclusions: Averaging Kernels: Figure 4: Temperature vs cm -1 cooling rate profile averaging kernel matrix diagonals for mid- latitude summer conditions 6. Averaging Kernel Matrix Results from AVE and MPACE Direct validation of cooling rate profile retrievals requires data from in situ vertically ascending or descending hemispheric radiometers that have the same overpass time as the remote sounder. In lieu of this, we perform a cross-comparison by analyzing other sets for atmospheric state information, and then comparing the calculated cooling rate to our retrieval. Figure 5: Deviation from a priori cooling rate profile (black) for spectral interval cm-1 for AIRS retrieved (red) and S-HIS calculated (blue) cooling rate profiles. (a): AVE 10 Flight: 10/31/2004, 24.8 N, E. (b): MPACE 11 flight: 10/10/2004, 62.7 N, E. A43B-0084 Comparison with IRIS-D: The stratosphere has changed substantially between the time of the operation of IRIS-D and AIRS. CO 2 has increased by over 50 ppmv, O 3 has decreased by 6% or more, and T has decreased by 3 K or more 12. All of these factors affect the cooling rate profile in the 15 µm band. With the cooling rate profile, the net flux at the tropopause and hence the radiative forcing can be determined. We have done preliminary analysis using the Integrated Global Radiosonde Archive (IGRA) 13 and found that night-time radiosonde observations (RAOBs) in conjunction with IRIS-D spectra will allow the characterization of stratospheric temperatures above 30 mbar with ~ 1 degree of freedom. Figure 6: Expected change in net tropopause flux over cm -1 band ( ) using ERA-40 T, H 2 O, and O 3 fields 8 and 323 and 379 ppmv for CO 2 for 1970 and 2001 respectively. Figure 7: Temperature averaging kernel diagonals for IRIS-D + RAOB data on retrieved pressure level vs. RAOB accuracy for USSTD 6. Right axis indicates total degrees of freedom of the signal.