Your search keyword '"Sophie Vandenbussche"' showing total 2 results

1. Two test-cases for synergistic detections in the Martian atmosphere: Carbon monoxide and methane

Author

Claude Camy-Peyret, E. De Wachter, Ann Carine Vandaele, Séverine Robert, Frank Daerden, M. De Mazière, Sophie Vandenbussche, and Lori Neary

Subjects

Materials science, 010504 meteorology & atmospheric sciences, Infrared, Infrared spectroscopy, Mars, 01 natural sciences, Methane, chemistry.chemical_compound, Far infrared, 0103 physical sciences, 010303 astronomy & astrophysics, Spectroscopy, 0105 earth and related environmental sciences, Remote sensing, Martian, CH4, Radiation, Atmosphere of Mars, ExoMars, Atomic and Molecular Physics, and Optics, Trace gas, Martian atmosphere, CO, chemistry, Future mission preparation, Trace Gas Orbiter, 13. Climate action, Carbon monoxide

Abstract

In the frame of the scientific preparation of ExoMars Trace Gas Orbiter (EMTGO), synergistic retrievals were performed on synthetic spectra of two different remote sensing instruments of the Martian atmosphere. To benefit from their diversity, we have simulated spectra of a Fourier transform spectrometer (FTS), working in the middle to far infrared and of a grating spectrometer (GA) working in the middle infrared. As control runs, non-synergistic retrievals were performed as well. Two molecules of interest in the Martian atmosphere were chosen to test this method: carbon monoxide and methane. Scenarios were selected and two different vibrational bands for each molecule were used to retrieve molecular volume mixing ratios. Synergistic retrievals for CO are useful both in solar occultation and in nadir, while for CH4, the concentration of which is expected to be very low, the results for FTS and GA in synergy are not as conclusive due to the weak signal in the ν4 vibrational band (covered by FTS) compared to the stronger ν3 band (covered by GA). Our results represent a first step to an optimized use of infrared spectra to be recorded in Martian orbit by two instruments of EMTGO.

Published

2017

2. On the retrieval of aerosol optical depth over cryosphere using passive remote sensing

Author

Sophie Vandenbussche, Linlu Mei, Emmanouil Proestakis, Sieglinde Callewaert, Vassilis Amiridis, John P. Burrows, Vladimir Rozanov, and Marco Vountas

Subjects

Radiometer, Soil Science, Geology, AATSR, Infrared atmospheric sounding interferometer, Aerosol optical depth, cryosphere, AERONET, Aerosol, Lidar, Emissivity, AATSR/SLSTR, Cryosphere, Environmental science, Computers in Earth Sciences, retrieval, Arctic Amplification, Remote sensing

Abstract

The lack of aerosol information over the cryosphere introduces large uncertainties to our understanding of phenomenon, known as the Arctic Amplification (AA) and its feedback mechanisms. The aerosol optical depth (AOD) describes the optical characteristics of aerosol loading. This paper describes a novel algorithm, which retrieves AOD above snow-covered regions from the measurements of the up-welling radiation at the top of atmosphere, observed by the Advanced Along-Track Scanning Radiometer (AATSR) and the Sea and Land Surface Temperature Radiometer (SLSTR) instruments. The algorithm optimizes the generic eXtensible Bremen Aerosol/cloud and surfacE parameters Retrieval (XBAER) approach for longer wavelengths over the cryosphere. The algorithm utilizes the characteristics of solar bidirectional distribution properties of snow and aerosol at wavelength 3.7 μm to derive above-snow-AOD. Since the impact of fine-mode aerosol on 3.7 μm is ignorable, the retrieved AOD in this manuscript represents mainly coarse-mode dominated part. A novel method to extract the solar reflection part at 3.7 μm is presented and used in the surface parameterization. Two aerosol types (sea saltdominated and dust-dominated) are used and the best-fit type is derived by an iterative procedure, using a LookUp-Table (LUT) approach. Sensitivity studies of the impact on the retrieved AOD using XBAER algorithm, which investigate the impacts of aerosol type, snow surface emissivity and potential cloud contamination under typical AATSR observation conditions, are presented. The sensitivity studies show that the surface parametrization and aerosol typing are suitable for the retrieval of above-snow-AOD over the Arctic snow-covered region. AOD observations retrieved in this study from AATSR (2002–2012) observation collocated with those from the Aerosol Robotic Network (AERONET) sites over Greenland show good agreement. 72.1% of the match-ups fall into the expected error envelope of ( ± 0.15AOD ± 0.025). The AATSR derived above-snow-AOD at 0.55 μm research product has also been compared with Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO) aerosol product, the Mineral Aerosols Profiling from Infrared Radiances (MAPIR) derived Infrared Atmospheric Sounding Interferometer (IASI) AOD research product, and the Modern-Era Retrospective analysis for Research and Applications, Version 2 (MERRA-2) AOD simulations over Greenland on April 2011. The comparison reveals that all datasets show similar patterns for the AOD above Greenland. The AOD is smaller in central Greenland and larger over the coastline regions. The XBAER derived above-snow-AOD has improved coverage, as compared to that of the existing AATSR aerosol product. The transition between above-snow-AOD and AOD derived over surrounding ocean surfaces does not indicate any systematic errors. Two aerosol transport events have been well-captured by the XBAER derived above-snow-AOD research product. The new algorithm is also applied to the SLSTR onboard Sentinel-3 demonstrating new SLSTR above-snow-AOD data products, and its value for research in the changing AOD during the period of Arctic Amplification.

Published

2020