Your search keyword '"Seidel, Felix C."' showing total 19 results

1. Optimal estimation of spectral surface reflectance in challenging atmospheres

Author

Thompson, David R., Babu, K.N., Braverman, Amy J., Eastwood, Michael L., Green, Robert O., Hobbs, Jonathan M., Jewell, Jeffrey B., Kindel, Bruce, Massie, Steven, Mishra, Manoj, Mathur, Aloke, Natraj, Vijay, Townsend, Philip A., Seidel, Felix C., and Turmon, Michael J.

Published

2019

2. Imaging spectrometer emulates Landsat: A case study with Airborne Visible Infrared Imaging Spectrometer (AVIRIS) and Operational Land Imager (OLI) data

Author

Seidel, Felix C., Stavros, E. Natasha, Cable, Morgan L., Green, Robert, and Freeman, Anthony

Published

2018

3. The Airborne Snow Observatory: Fusion of scanning lidar, imaging spectrometer, and physically-based modeling for mapping snow water equivalent and snow albedo

Author

Painter, Thomas H., Berisford, Daniel F., Boardman, Joseph W., Bormann, Kathryn J., Deems, Jeffrey S., Gehrke, Frank, Hedrick, Andrew, Joyce, Michael, Laidlaw, Ross, Marks, Danny, Mattmann, Chris, McGurk, Bruce, Ramirez, Paul, Richardson, Megan, Skiles, S. McKenzie, Seidel, Felix C., and Winstral, Adam

Published

2016

4. Advanced radiometry measurements and Earth science applications with the Airborne Prism Experiment (APEX)

Author

Schaepman, Michael E., Jehle, Michael, Hueni, Andreas, D'Odorico, Petra, Damm, Alexander, Weyermann, Jürg, Schneider, Fabian D., Laurent, Valérie, Popp, Christoph, Seidel, Felix C., Lenhard, Karim, Gege, Peter, Küchler, Christoph, Brazile, Jason, Kohler, Peter, De Vos, Lieve, Meuleman, Koen, Meynart, Roland, Schläpfer, Daniel, Kneubühler, Mathias, and Itten, Klaus I.

Published

2015

5. Fire Influence on Regional to Global Environments and Air Quality (FIREX‐AQ)

Author

Warneke, Carsten, Schwarz, Joshua P., Washenfelder, Rebecca A., Wiggins, Elizabeth B., Moore, Richard H., Anderson, Bruce E., Jordan, Carolyn, Yacovitch, Tara I., Herndon, Scott C., Liu, Shang, Kuwayama, Toshihiro, Jaffe, Daniel, Dibb, Jack, Johnston, Nancy, Selimovic, Vanessa, Yokelson, Robert, Giles, David M., Holben, Brent N., Goloub, Philippe, Popovici, Ioana, Trainer, Michael, Kumar, Aditya, Pierce, R. Bradley, Kalashnikova, Olga, Fahey, David, Roberts, James, Gargulinski, Emily M., Peterson, David A., Ye, Xinxin, Thapa, Laura H., Saide, Pablo E., Fite, Charles H., Holmes, Christopher D., Wang, Siyuan, Frost, Gregory, Coggon, Matthew M., Decker, Zachary C. J., Stockwell, Chelsea E., Xu, Lu, Gkatzelis, Georgios, Aikin, Kenneth, Lefer, Barry, Kaspari, Jackson, Griffin, Debora, Zeng, Linghan, Al-Saad, Jassim, Weber, Rodney, Hastings, Meredith, Chai, Jiajue, Wolfe, Glenn M., Hanisco, Thomas F., Liao, Jin, Campuzano Jost, Pedro, Guo, Hongyu, Jimenez, Jose L., Crawford, James, Brown, Steven S., Brewer, Wm. Alan, Soja, Amber, and Seidel, Felix C.

Subjects

Atmospheric Science, Geophysics, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), ddc:550

Abstract

The NOAA/NASA Fire Influence on Regional to Global Environments and Air Quality (FIREX-AQ) experiment was a multi-agency, inter-disciplinary research effort to: (a) obtain detailed measurements of trace gas and aerosol emissions from wildfires and prescribed fires using aircraft, satellites and ground-based instruments, (b) make extensive suborbital remote sensing measurements of fire dynamics, (c) assess local, regional, and global modeling of fires, and (d) strengthen connections to observables on the ground such as fuels and fuel consumption and satellite products such as burned area and fire radiative power. From Boise, ID western wildfires were studied with the NASA DC-8 and two NOAA Twin Otter aircraft. The high-altitude NASA ER-2 was deployed from Palmdale, CA to observe some of these fires in conjunction with satellite overpasses and the other aircraft. Further research was conducted on three mobile laboratories and ground sites, and 17 different modeling forecast and analyses products for fire, fuels and air quality and climate implications. From Salina, KS the DC-8 investigated 87 smaller fires in the Southeast with remote and in-situ data collection. Sampling by all platforms was designed to measure emissions of trace gases and aerosols with multiple transects to capture the chemical transformation of these emissions and perform remote sensing observations of fire and smoke plumes under day and night conditions. The emissions were linked to fuels consumed and fire radiative power using orbital and suborbital remote sensing observations collected during overflights of the fires and smoke plumes and ground sampling of fuels.

Published

2023

6. Airborne imaging spectroscopy to monitor urban mosquito microhabitats

Author

Thompson, David R., de la Torre Juárez, Manuel, Barker, Christopher M., Holeman, Jodi, Lundeen, Sarah, Mulligan, Steve, Painter, Thomas H., Podest, Erika, Seidel, Felix C., and Ustinov, Eugene

Published

2013

7. Introducing the MISR level 2 near real-time aerosol product.

Author

Witek, Marcin L., Garay, Michael J., Diner, David J., Bull, Michael A., Seidel, Felix C., Nastan, Abigail M., and Hansen, Earl G.

Subjects

ATMOSPHERIC aerosols, AEROSOLS, WATER demand management, AEROSOL analysis, AIR quality, HUMAN ecology

Abstract

Atmospheric aerosols are an important element of Earth's climate system and have significant impacts on the environment and on human health. Global aerosol modeling has been increasingly used for operational forecasting and as support for decision making. For example, aerosol analyses and forecasts are routinely used to provide air quality information and alerts in both civilian and military applications. The growing demand for operational aerosol forecasting calls for additional observational data that can be assimilated into models to improve model accuracy and predictive skill. These factors have motivated the development, testing, and release of a new near real-time (NRT) level 2 (L2) aerosol product from the Multi-angle Imaging SpectroRadiometer (MISR) instrument on NASA's Terra platform. The NRT product capitalizes on the unique attributes of the MISR aerosol retrieval approach and product contents, such as reliable aerosol optical depth as well as aerosol microphysical information. Several modifications are described that allow for rapid product generation within a 3 h window following acquisition of the satellite observations. Implications for the product quality and consistency are discussed and compared to the current operational L2 MISR aerosol product. Several ways of implementing additional use-specific retrieval screenings are also highlighted. [ABSTRACT FROM AUTHOR]

Published

2021

8. Introducing the 4.4 km spatial resolution Multi-Angle Imaging SpectroRadiometer (MISR) aerosol product.

Author

Garay, Michael J., Witek, Marcin L., Kahn, Ralph A., Seidel, Felix C., Limbacher, James A., Bull, Michael A., Diner, David J., Hansen, Earl G., Kalashnikova, Olga V., Lee, Huikyo, Nastan, Abigail M., and Yu, Yan

Subjects

AEROSOLS, ATMOSPHERIC sciences, SPECTRORADIOMETER, OPTICAL depth (Astrophysics), SERVER farms (Computer network management), RADIOACTIVE aerosols, WATER vapor

Abstract

The Multi-angle Imaging SpectroRadiometer (MISR) instrument has been operational on the National Aeronautics and Space Administration (NASA) Earth Observing System (EOS) Terra satellite since early 2000, creating an extensive data set of global Earth observations. Here we introduce the latest version of the MISR aerosol products. The level 2 (swath) product, which is reported on a 4.4 km spatial grid, is designated as version 23 (V23) and contains retrieved aerosol optical depth (AOD) and aerosol particle property information derived from MISR's multi-angle observations over both land and water. The changes from the previous version of the algorithm (V22) have significant impacts on the data product and its interpretation. The V23 data set is created from two separate retrieval algorithms that are applied over dark water and land surfaces, respectively. Besides increasing the horizontal resolution to 4.4 km compared with the coarser 17.6 m resolution in V22 and streamlining the format and content, the V23 product has added geolocation information, pixel-level uncertainty estimates, and improved cloud screening. MISR data can be obtained from the NASA Langley Research Center Atmospheric Science Data Center at https://eosweb.larc.nasa.gov/project/misr/misr%5ftable (last access: 11 October 2019). The version number for the V23 level 2 aerosol product is F13_0023. The level 3 (gridded) aerosol product is still reported at 0.5∘×0.5∘ spatial resolution with results aggregated from the higher-resolution level 2 data. The format and content at level 3 have also been updated to reflect the changes made at level 2. The level 3 product associated with the V23 level 2 product version is designated as F15_0032. Both the level 2 and level 3 products are now provided in NetCDF format. [ABSTRACT FROM AUTHOR]

Published

2020

9. Introducing the 4.4 km Spatial Resolution MISR Aerosol Product.

Author

Garay, Michael J., Witek, Marcin L., Kahn, Ralph A., Seidel, Felix C., Limbacher, James A., Bull, Michael A., Diner, David J., Hansen, Earl G., Kalashnikova, Olga V., Huikyo Lee, Nastan, Abigail M., and Yan Yu

Subjects

AEROSOLS, ATMOSPHERIC sciences, OPTICAL depth (Astrophysics), SERVER farms (Computer network management), RADIOACTIVE aerosols, WATER vapor, MANUFACTURED products

Abstract

The Multi-angle Imaging SpectroRadiometer (MISR) instrument has been operational on the National Aeronautics and Space Administration (NASA) Earth Observing System (EOS) Terra satellite since early 2000, creating an extensive data set of global Earth observations. Here we introduce the latest version of the MISR aerosol products. The Level 2 (swath) product, which is reported on a 4.4 km spatial grid, is designated Version 23 (V23) and contains retrieved aerosol optical depth (AOD) and aerosol particle property information derived from MISR's multi-angle observations over both land and water. The changes from the previous version of the algorithm (V22) have significant impacts on the data product and its interpretation. The V23 data set is created from two separate retrieval algorithms that are applied over dark water and land surfaces, respectively. Besides increasing the horizontal resolution to 4.4 km compared with the coarser 17.6 m resolution in V22, and streamlining the format and content, the V23 product has added geolocation information, pixel-level uncertainty estimates, and improved cloud screening. MISR data can be obtained from the NASA Langley Research Center Atmospheric Science Data Center at https://eosweb.larc.nasa.gov/project/misr/misr_table. The version number for the V23 Level 2 aerosol product is F13_0023. The Level 3 (gridded) aerosol product is still reported at 0.5° x 0.5° spatial resolution with results aggregated from the higher-resolution Level 2 data. The format and content at Level 3 have also been updated to reflect the changes made at Level 2. The Level 3 product associated with the V23 Level 2 product version is designated F15_0032. Both the Level 2 and Level 3 products are now provided in NetCDF format. [ABSTRACT FROM AUTHOR]

Published

2019

10. Coupled Retrieval of Liquid Water Cloud and Above‐Cloud Aerosol Properties Using the Airborne Multiangle SpectroPolarimetric Imager (AirMSPI).

Author

Xu, Feng, van Harten, Gerard, Diner, David J., Davis, Anthony B., Seidel, Felix C., Rheingans, Brian, Tosca, Mika, Alexandrov, Mikhail D., Cairns, Brian, Ferrare, Richard A., Burton, Sharon P., Fenn, Marta A., Hostetler, Chris A., Wood, Robert, and Redemann, Jens

Abstract

Abstract: An optimization algorithm is developed to retrieve liquid water cloud properties including cloud optical depth (COD), droplet size distribution and cloud top height (CTH), and above‐cloud aerosol properties including aerosol optical depth (AOD), single‐scattering albedo, and microphysical properties from sweep‐mode observations by Jet Propulsion Laboratory's Airborne Multiangle SpectroPolarimetric Imager (AirMSPI) instrument. The retrieval is composed of three major steps: (1) initial estimate of the mean droplet size distribution across the entire image of 80–100 km along track by 10–25 km across track from polarimetric cloudbow observations, (2) coupled retrieval of image‐scale cloud and above‐cloud aerosol properties by fitting the polarimetric data at all observation angles, and (3) iterative retrieval of 1‐D radiative transfer‐based COD and droplet size distribution at pixel scale (25 m) by establishing relationships between COD and droplet size and fitting the total radiance measurements. Our retrieval is tested using 134 AirMSPI data sets acquired during the National Aeronautics and Space Administration (NASA) field campaign ObseRvations of Aerosols above CLouds and their intEractionS. The retrieved above‐cloud AOD and CTH are compared to coincident HSRL‐2 (HSRL‐2, NASA Langley Research Center) data, and COD and droplet size distribution parameters (effective radius reff and effective variance veff) are compared to coincident Research Scanning Polarimeter (RSP) (NASA Goddard Institute for Space Studies) data. Mean absolute differences between AirMSPI and HSRL‐2 retrievals of above‐cloud AOD at 532 nm and CTH are 0.03 and <0.5 km, respectively. At RSP's footprint scale (~ 323 m), mean absolute differences between RSP and AirMSPI retrievals of COD, reff, and veff in the cloudbow area are 2.33, 0.69 μm, and 0.020, respectively. Neglect of smoke aerosols above cloud leads to an underestimate of image‐averaged COD by ~15%. [ABSTRACT FROM AUTHOR]

Published

2018

11. Improving MISR AOD Retrievals With Low-Light-Level Corrections for Veiling Light.

Author

Witek, Marcin L., Diner, David J., Garay, Michael J., Feng Xu, Bull, Michael A., and Seidel, Felix C.

Subjects

OPERATIONAL psychology, AIR pollution, REMOTE sensing, DETECTORS, SPECTRORADIOMETER

Abstract

Operational retrievals of aerosol optical depth (AOD) from Multi-angle Imaging SpectroRadiometer (MISR) data have been shown to have a high bias in pristine oceanic areas. One line of evidence involves comparison with Maritime Aerosol Network (MAN) observations, including the areas of low aerosol loading close to Antarctica. In this paper, a principal reason for the AOD overestimation is identified, which is stray light measured by the MISR cameras in dark regions of high-contrast scenes. A small fraction of the light from surrounding bright areas, such as clouds or sea ice, is redistributed to dark areas, artificially increasing their brightness. Internal reflections and light scattering from optical elements in MISR's pushbroom cameras contribute to this veiling light effect. A simple correction model is developed that relies on the average scene brightness and an empirically determined set of veiling light coefficients for each MISR camera and wavelength. Several independent methods are employed to determine these coefficients. Three sets of coefficients are further implemented and tested in prototype MISR 4.4-km AOD retrievals. The results show dramatic improvements in retrieved AODs compared against MAN observations and the currently operational V22 MISR retrievals. For the best performing set of coefficients, the bias is reduced by 51%, from 0.039 to 0.019, the RMSE is lowered by 19%, from 0.062 to 0.050, and 84% of retrievals fall within the uncertainty envelope compared with 66% of retrievals in V22. The best performing set will be implemented operationally in the next V23 MISR AOD product release. [ABSTRACT FROM AUTHOR]

Published

2018

12. New approach to the retrieval of AOD and its uncertainty from MISR observations over dark water.

Author

Witek, Marcin L., Garay, Michael J., Diner, David J., Bull, Michael A., and Seidel, Felix C.

Subjects

ATMOSPHERIC aerosols, OPTICAL depth (Astrophysics), SPECTRORADIOMETER, ASTRONOMICAL observations, ATMOSPHERIC ozone

Abstract

A new method for retrieving aerosol optical depth (AOD) and its uncertainty from Multi-angle Imaging SpectroRadiometer (MISR) observations over dark water is outlined. MISR's aerosol retrieval algorithm calculates cost functions between observed and pre-simulated radiances for a range of AODs (from 0.0 to 3.0) and a prescribed set of aerosol mixtures. The previous version 22 (V22) operational algorithm considered only the AOD that minimized the cost function for each aerosol mixture and then used a combination of these values to compute the final, best estimate AOD and associated uncertainty. The new approach considers the entire range of cost functions associated with each aerosol mixture. The uncertainty of the reported AOD depends on a combination of (a) the absolute values of the cost functions for each aerosol mixture, (b) the widths of the cost function distributions as a function of AOD, and (c) the spread of the cost function distributions among the ensemble of mixtures. A key benefit of the new approach is that, unlike the V22 algorithm, it does not rely on empirical thresholds imposed on the cost function to determine the success or failure of a particular mixture. Furthermore, a new aerosol retrieval confidence index (ARCI) is established that can be used to screen high-AOD retrieval blunders caused by cloud contamination or other factors. Requiring ARCI  ≥ 0.15 as a condition for retrieval success is supported through statistical analysis and outperforms the thresholds used in the V22 algorithm. The described changes to the MISR dark water algorithm will become operational in the new MISR aerosol product (V23), planned for release in 2017. [ABSTRACT FROM AUTHOR]

Published

2018

13. New approach to the retrieval of AOD and its uncertainty from MISR observations over dark water.

Author

Witek, Marcin L., Garay, Michael J., Diner, David J., Bull, Michael A., and Seidel, Felix C.

Subjects

ATMOSPHERIC aerosols, MISR (Spectroradiometers), UNCERTAINTY (Information theory)

Abstract

A new method for retrieving aerosol optical depth (AOD) and its uncertainty from Multi-angle Imaging SpectroRadiometer (MISR) observations over dark water is outlined. MISR's aerosol retrieval algorithm calculates cost functions between observed and pre-simulated radiances for a range of AODs (from 0.0 to 3.0) and a prescribed set of aerosol mixtures. The previous Version 22 (V22) operational algorithm considered only the AOD that minimized the cost function for each aerosol mixture, then used a combination of these values to compute the final, best estimate" AOD and associated uncertainty. The new approach considers the entire range of cost functions associated with each aerosol mixture. The uncertainty of the reported AOD depends on a combination of a) the absolute values of the cost functions for each aerosol mixture, b) the widths of the cost function distributions as a function of AOD, and c) the spread of the cost function distributions among the ensemble of mixtures. A key benefit of the new approach is that, unlike the V22 algorithm, it does not rely on arbitrary thresholds imposed on the cost function to determine the success or failure of a particular mixture. Furthermore, a new Aerosol Retrieval Confidence Index (ARCI) is established that can be used to screen high-AOD retrieval blunders caused by cloud contamination or other factors. Requiring ARCI ≥ 0.15 as a condition for retrieval success is supported through statistical analysis and outperforms the thresholds used in the V22 algorithm. The described changes to the MISR dark water algorithm will become operational in the new MISR aerosol product (V23), planned for release in 2017. [ABSTRACT FROM AUTHOR]

Published

2017

14. Coupled retrieval of aerosol properties and land surface reflection using the Airborne Multiangle SpectroPolarimetric Imager.

Author

Xu, Feng, Harten, Gerard, Diner, David J., Kalashnikova, Olga V., Seidel, Felix C., Bruegge, Carol J., and Dubovik, Oleg

Published

2017

15. Attributing Accelerated SummertimeWarming in the Southeast United States to Recent Reductions in Aerosol Burden: Indications from Vertically-Resolved Observations.

Author

Tosca, Mika G., Campbell, James, Garay, Michael, Lolli, Simone, Seidel, Felix C., Marquis, Jared, and Kalashnikova, Olga

Subjects

CLIMATE change, GLOBAL warming, AIR quality, ATMOSPHERIC aerosols, GREENHOUSE gases

Abstract

During the twentieth century, the southeast United States cooled, in direct contrast with widespread global and hemispheric warming. While the existing literature is divided on the cause of this so-called "warming hole," anthropogenic aerosols have been hypothesized as playing a primary role in its occurrence. In this study, unique satellite-based observations of aerosol vertical profiles are combined with a one-dimensional radiative transfer model and surface temperature observations to diagnose how major reductions in summertime aerosol burden since 2001 have impacted surface temperatures in the southeast US. We show that a significant improvement in air quality likely contributed to the elimination of the warming hole and acceleration of the positive temperature trend observed in recent years. These reductions coincide with a new EPA rule that was implemented between 2006 and 2010 that revised the fine particulate matter standard downward. Similar to the southeast US in the twentieth century, other regions of the globe may experience masking of long-term warming due to greenhouse gases, especially those with particularly poor air quality [ABSTRACT FROM AUTHOR]

Published

2017

16. Joint retrieval of aerosol and water-leaving radiance from multispectral, multiangular and polarimetric measurements over ocean.

Author

Feng Xu, Dubovik, Oleg, Peng-Wang Zhai, Diner, David J., Kalashnikova, Olga V., Seidel, Felix C., Litvinov, Pavel, Bovchaliuk, Andrii, Garay, Michael J., van Harten, Gerard, and Davis, Anthony B.

Subjects

ATMOSPHERIC aerosol measurement, OCEAN-atmosphere interaction, SEA salt aerosols, ATMOSPHERIC aerosol analysis, ATMOSPHERIC chemistry

Abstract

An optimization approach has been developed for simultaneous retrieval of aerosol properties and normalized water-leaving radiance (nLw) from multispectral, multiangular, and polarimetric observations over ocean. The main features of the method are (1) use of a simplified bio-optical model to estimate nLw, followed by an empirical refinement within a specified range to improve its accuracy; (2) improved algorithm convergence and stability by applying constraints on the spatial smoothness of aerosol loading and Chlorophyll a (Chl a) concentration across neighboring image patches and spectral constraints on aerosol optical properties and nLw across relevant bands; and (3) enhanced Jacobian calculation by modeling and storing the radiative transfer (RT) in aerosol/Rayleigh mixed layer, pure Rayleigh-scattering layers, and ocean medium separately, then coupling them to calculate the field at the sensor. This approach avoids unnecessary and time-consuming recalculations of RT in unperturbed layers in Jacobian evaluations. The Markov chain method is used to model RT in the aerosol/Rayleigh mixed layer and the doubling method is used for the uniform layers of the atmosphere–ocean system. Our optimization approach has been tested using radiance and polarization measurements acquired by the Airborne Multiangle SpectroPolarimetric Imager (AirMSPI) over the AERONET USC_SeaPRISM ocean site (6 February 2013) and near the AERONET La Jolla site (14 January 2013), which, respectively, reported relatively high and low aerosol loadings. Validation of the results is achieved through comparisons to AERONET aerosol and ocean color products. For comparison, the USC_SeaPRISM retrieval is also performed by use of the Generalized Retrieval of Aerosol and Surface Properties algorithm (Dubovik et al., 2011). Uncertainties of aerosol and nLw retrievals due to random and systematic instrument errors are analyzed by truth-in/truth-out tests with three Chl a concentrations, five aerosol loadings, three different types of aerosols, and nine combinations of solar incidence and viewing geometries. [ABSTRACT FROM AUTHOR]

Published

2016

17. Optimizing irradiance estimates for coastal and inland water imaging spectroscopy.

Author

Thompson, David R., Seidel, Felix C., Gao, Bo Cai, Gierach, Michelle M., Green, Robert O., Kudela, Raphael M., and Mouroulis, Pantazis

Published

2015

18. Imaging spectroscopy of albedo and radiative forcing by light-absorbing impurities in mountain snow.

Author

Painter, Thomas H., Seidel, Felix C., Bryant, Ann C., McKenzie Skiles, S., and Rittger, Karl

Published

2013

19. Assessing the Potential of Geostationary Satellites for Aerosol Remote Sensing Based on Critical Surface Albedo.

Author

Ceamanos, Xavier, Moparthy, Suman, Carrer, Dominique, and Seidel, Felix C.

Subjects

GEOSTATIONARY satellites, REMOTE sensing, ALBEDO, AEROSOLS, ATMOSPHERIC aerosols, ARTIFICIAL satellite tracking, ARTIFICIAL satellites

Abstract

Geostationary satellites are increasingly used for the detection and tracking of atmospheric aerosols and, in particular, of the aerosol optical depth (AOD). The main advantage of these spaceborne platforms in comparison with polar orbiting satellites is their capability to observe the same region of the Earth several times per day with varying geometry. This provides a wealth of information that makes aerosol remote sensing possible when combined with the multi-spectral capabilities of the on-board imagers. Nonetheless, the suitability of geostationary observations for AOD retrieval may vary significantly depending on their spatial, spectral, and temporal characteristics. In this work, the potential of geostationary satellites was assessed based on the concept of critical surface albedo (CSA). CSA is linked to the sensitivity of each spaceborne observation to the aerosol signal, as it is defined as the value of surface albedo for which a varying AOD does not alter the satellite measurement. In this study, the sensitivity to aerosols was determined by estimating the difference between the surface albedo of the observed surface and the corresponding CSA (referred to as dCSA). The values of dCSA were calculated for one year of observations from the Meteosat Second Generation (MSG) spacecraft, based on radiative transfer simulations and information on the satellite acquisition geometry and the properties of the observed surface and aerosols. Different spectral channels from MSG and the future Meteosat Third Generation-Imager were used to study their distinct capabilities for aerosol remote sensing. Results highlight the significant but varying potential of geostationary observations across the observed Earth disk and for different time scales (i.e., diurnal, seasonal, and yearly). For example, the capability of sensing multiples times during the day is revealed to be a notable strength. Indeed, the value of dCSA often fluctuates significantly for a given day, which makes some instants of time more suitable for aerosol retrieval than others. This study determines these instants of time as well as the seasons and the sensing wavelengths that increase the chances for aerosol remote sensing thanks to the variations of dCSA. The outcomes of this work can be used for the development and refinement of AOD retrieval algorithms through the use of the concept of CSA. Furthermore, results can be extrapolated to other present-day geostationary satellites such as Himawari-8/9 and GOES-16/17. [ABSTRACT FROM AUTHOR]

Published

2019