Spectro-photometry of Phobos simulants: II. Effects of porosity

TL;DR

This study investigates how porosity affects the spectro-photometric properties of Phobos surface simulants across visible, near-infrared, and mid-infrared wavelengths, revealing subtle variations and dependencies on composition and surface roughness.

Contribution

It provides new insights into the effects of porosity on small body surface properties using Phobos simulants, relevant for upcoming space missions.

Findings

No strong spectral variations between porous and compact samples in visible and near-infrared.

One simulant shows a slope bluing with increased porosity, indicating compositional effects.

Porosity influences phase reddening and scattering behavior, affecting surface roughness estimates.

Abstract

Surface porosity has been found to be an important property for small bodies. Some asteroids and comets can exhibit an extremely high surface porosity in the first millimeter layer. This layer may be produced by various processes and maintained by the lack of an atmosphere. However, the influence of porosity on the spectro-photometric properties of small body surfaces is not yet fully understood. In this study, we looked into the effect of porosity on the spectro-photometric properties of Phobos regolith spectroscopic simulants; created by mixing the simulants with ultra-pure water, producing ice-dust particles, and then sublimating the water. The reflectance spectroscopic properties in the visible and near-infrared (0.5-4.2 $\mu$m) show no strong variations between the porous and compact samples. However, one simulant exhibits a bluing of the slope after increasing porosity, providing possible insights into the differences between the blue and red units observed on Phobos. In the mid-infrared range, a contrast increase of the 10-$\mu$m emissivity plateau due to silicates is observed. Photometry reveals a modification in the phase reddening behavior between the compact powder and the sublimation residue for both simulants. However, the observed behavior is different between the simulants, suggesting that the phase reddening may be dependent on the composition of the simulants. The phase curve also appears to be modified by the addition of porosity, with a higher contribution of forward scattering observed for the sublimation residue. The derivation of the Hapke parameters indicates an increase in roughness for the porous sample, but no significant modification of the opposition effect. This study aims to provide new insights into the understanding of porosity by using two Phobos simulants in the context of the upcoming JAXA/Martian Moons eXploration mission.