Abstract
We introduce a novel spectral fingerprinting scheme that can be used to derive long-term atmospheric temperature and water vapor anomalies from hyperspectral infrared sounders such as Cross-track Infrared Sounder (CrIS) and Atmospheric Infrared Sounder (AIRS). It is a challenging task to derive climate trends from real satellite observations due to the difficulty of carrying out accurate cloudy radiance simulations and constructing radiometrically consistent radiative kernels. To address these issues, we use a principal component based radiative transfer model (PCRTM) to perform multiple scattering calculations of clouds and a PCRTM-based physical retrieval algorithm to derive radiometrically consistent radiative kernels from real satellite observations. The capability of including the cloud scattering calculations in the retrieval process allows the establishment of a rigorous radiometric fitting to satellite-observed radiances under all-sky conditions. The fingerprinting solution is directly obtained via an inverse relationship between the atmospheric anomalies and the corresponding spatiotemporally averaged radiance anomalies. Since there is no need to perform Level 2 retrievals on each individual satellite footprint for the fingerprinting approach, it is much more computationally efficient than the traditional way of producing climate data records from spatiotemporally averaged Level 2 products. We have applied the spectral fingerprinting method to six years of CrIS and 16 years of AIRS data to derive long-term anomaly time series for atmospheric temperature and water vapor profiles. The CrIS and AIRS temperature and water vapor anomalies derived from our spectral fingerprinting method have been validated using results from the PCRTM-based physical retrieval algorithm and the AIRS operational retrieval algorithm, respectively.
Highlights
Spectral information from outgoing longwave radiation (OLR) can be used to determine the contributions of individual climate forcing factors to the total change of Top-Of-Atmosphere (TOA) radiation energy
Climate spectral fingerprinting has been demonstrated as a promising approach to efficiently carry out climate trend and anomaly studies using the OLR spectral measurements
We introduce a novel fingerprinting scheme that can be used to derive atmospheric anomalies from real hyperspectral sounder data
Summary
Spectral information from outgoing longwave radiation (OLR) can be used to determine the contributions of individual climate forcing factors to the total change of Top-Of-Atmosphere (TOA) radiation energy. We introduce in this paper a novel fingerprinting approach suitable for deriving climate change signals from hyperspectral sounder observations under all-sky conditions This approach uses FOV retrieval results from selected hyperspectral sounder observations to build fingerprinting radiative kernels that can be used to process the complete hyperspectral sounder data set of multiple years. Such an approach combines the benefit of using the physical retrieval to establish the radiometric consistency check and the benefit of using the fingerprinting methodology to reduce the computational cost and facilitate the climate trend analysis.
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