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Auteurs principaux: Fornasier, S., Wargnier, A., Hasselmann, P. H., Tirsch, D., Matz, K. -D., Doressoundiram, A., Gautier, T., Barucci, M. A.
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2403.12156
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author Fornasier, S.
Wargnier, A.
Hasselmann, P. H.
Tirsch, D.
Matz, K. -D.
Doressoundiram, A.
Gautier, T.
Barucci, M. A.
author_facet Fornasier, S.
Wargnier, A.
Hasselmann, P. H.
Tirsch, D.
Matz, K. -D.
Doressoundiram, A.
Gautier, T.
Barucci, M. A.
contents This study aims to analyze Phobos' photometric properties using Mars Express mission observations to support the Martian Moons eXploration mission. We analyzed resolved images of Phobos acquired between 2004 and 2022 by the HRSC and the SRC cameras on board the Mars Express spacecraft. We performed photometric analysis using the Hapke model for both integrated and disk-resolved data. The Phobos phase function has a strong opposition effect due to shadow hiding, with an amplitude and a half-width of the opposition surge of 2.28$\pm$0.03 and 0.0573$\pm$0.0001, respectively. Overall, the surface of Phobos is dark, with a geometric albedo of 6.8 % in the green filter and backscattering. We also found a surface porosity of 87\%, indicating the presence of a thick dust mantle or of fractal aggregates on the top surface. The SSA maps revealed high reflectance variability, with the blue unit area in the northeast Stickney rim being up to 65\% brighter than average, while the Stickney floor is among the darkest regions, with reflectance 10 to 20% lower than average. Photometric modeling of the regions of interest selected in the red and blue units indicates that red unit terrains have a stronger opposition effect and a smaller SSA value than the blue ones, but they have similar porosity and backscattering properties. The HRSC data provide a unique investigation of the Phobos phase function and opposition surge, which is valuable information for the MMX observational planning. The Phobos opposition surge, surface porosity, phase integral, and spectral slope are very similar to the values observed for the comet 67P and for Jupiter family comets in general. Based on these similarities, we formulate a hypothesis that the Mars satellites might be the results of a binary or bilobated comet captured by Mars.
format Preprint
id arxiv_https___arxiv_org_abs_2403_12156
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Phobos photometric properties from Mars Express HRSC observations
Fornasier, S.
Wargnier, A.
Hasselmann, P. H.
Tirsch, D.
Matz, K. -D.
Doressoundiram, A.
Gautier, T.
Barucci, M. A.
Earth and Planetary Astrophysics
This study aims to analyze Phobos' photometric properties using Mars Express mission observations to support the Martian Moons eXploration mission. We analyzed resolved images of Phobos acquired between 2004 and 2022 by the HRSC and the SRC cameras on board the Mars Express spacecraft. We performed photometric analysis using the Hapke model for both integrated and disk-resolved data. The Phobos phase function has a strong opposition effect due to shadow hiding, with an amplitude and a half-width of the opposition surge of 2.28$\pm$0.03 and 0.0573$\pm$0.0001, respectively. Overall, the surface of Phobos is dark, with a geometric albedo of 6.8 % in the green filter and backscattering. We also found a surface porosity of 87\%, indicating the presence of a thick dust mantle or of fractal aggregates on the top surface. The SSA maps revealed high reflectance variability, with the blue unit area in the northeast Stickney rim being up to 65\% brighter than average, while the Stickney floor is among the darkest regions, with reflectance 10 to 20% lower than average. Photometric modeling of the regions of interest selected in the red and blue units indicates that red unit terrains have a stronger opposition effect and a smaller SSA value than the blue ones, but they have similar porosity and backscattering properties. The HRSC data provide a unique investigation of the Phobos phase function and opposition surge, which is valuable information for the MMX observational planning. The Phobos opposition surge, surface porosity, phase integral, and spectral slope are very similar to the values observed for the comet 67P and for Jupiter family comets in general. Based on these similarities, we formulate a hypothesis that the Mars satellites might be the results of a binary or bilobated comet captured by Mars.
title Phobos photometric properties from Mars Express HRSC observations
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2403.12156