- Names
-
- A. Wargnier
- T. Gautier
- A. Doressoundiram
- G. Poggiali
- P. Beck
- O. Poch
- E. Quirico
- T. Nakamura
- H. Miyamoto
- S. Kameda
- P.H. Hasselmann
- N. Ruscassier
- A. Buch
- S. Fornasier
- M.A. Barucci
- Title
- Spectro-photometry of Phobos simulants I. Detectability of hydrated minerals and organic bands
- Abstract
- Previous Mars Reconnaissance Orbiter and Mars Express observations of Phobos and Deimos, the moons of Mars, have improved our understanding of these small bodies. However, their formation and composition remain poorly constrained. Physical and spectral properties suggest that Phobos may be a weakly thermal-altered captured asteroid but the dynamical properties of the martian system suggest a formation by giant collision similar to the Earth moon. In 2027, the JAXA’s MMX mission aims to address these outstanding questions. We undertook measurements with a new simulant called OPPS (Observatory of Paris Phobos Simulant) which closely matches Phobos reflectance spectra from the visible to the mid-infrared wavelength range. The simulant was synthesized using a mixture of olivine, saponite, anthracite, and coal. Since observation geometry strongly influences the photometry and spectra of the light reflected from planetary surfaces, we evaluated the parameters obtained by modeling the phase curves – obtained through laboratory measurements – of two different Phobos simulants (UTPS-TB and OPPS) using Hapke IMSA model. Our results show that the photometric properties of Phobos simulants are not fully consistent with those of carbonaceous chondrites and martian meteorites. We also investigated the detection of volatiles/organic compounds and hydrated minerals, as the presence of such components is expected on Phobos in the hypothesis of a captured primitive asteroid. To investigate their detectability, we examined the variability of the 3.28 μm and 3.42 μm absorption bands related to aliphatic/aromatic carbon (as a proxy of organic material), as well as the 2.7 μmO-H feature in a Phobos laboratory spectroscopic simulant. The results indicate that a significant amount of organic compounds is required for the detection of C-H bands at 3.4 μm. The bands at 3.28 and 3.42 μm are faint (less than 2%) when ∼3 wt.% of organic compounds are present in the simulant and are likely undetectable by the MIRS spectrometer onboard the MMX mission. When the concentration of aliphatic and aromatic compounds is increased to 6 wt.%, a positive detection starts to become more plausible using remote sensing infrared spectroscopy. In contrast, the 2.7 μm absorption band, due to hydrated minerals, is much deeper and easier to detect than C-H organic features at the same concentration levels. The feature is still clearly detectable even when the simulant contains only 3 vol.% of phyllosilicates, corresponding to 0.7 wt.% OH groups. Posing limits on detectability of some possible key components of Phobos surface will be pivotal to prepare and interpret future observations of the MIRS spectrometer as well as TENGOO and OROCHI cameras onboard MMX mission.
- Keywords
- spectroscopy, planetary sciences
- Content
- spectral data, planetary sciences, material-matter
- Document type
- article
- Publication state
- in press