Visible and near-infrared reflectance of hyperfine and hyperporous particulate surfaces

TL;DR

This study investigates the reflectance properties of hyperfine and hyperporous particulate surfaces in the visible and near-infrared range to better understand the physical state of Solar System bodies like comets and asteroids.

Contribution

The paper introduces a novel technique to produce and measure hyperfine particles of astrophysical materials and analyzes their spectral behavior in hyperporous states.

Findings

Hyperfine particles show decreased absorption features and spectral blueing.

Hyperporous hyperfine surfaces exhibit even shallower absorption and more pronounced blueing.

Surface spectral features are influenced more by physical grain size and porosity than composition.

Abstract

The composition of Solar System surfaces can be inferred through reflectance and emission spectroscopy, by comparing these observations to laboratory measurements and radiative transfer models. While several populations of objects appear to be covered by sub-micrometre sized particles (referred to as hyperfine), there are limited studies on reflectance and emission of particulate surfaces composed of particles smaller than the visible and infrared wavelengths. We have undertaken an effort to determine the reflectance of hyperfine particulate surfaces in conjunction with high-porosity, in order to simulate the physical state of cometary surfaces and their related asteroids (P- and D-types). In this work, we present a technique developed to produce hyperfine particles of astrophysical relevant materials. Hyperfine powders were prepared and measured in reflectance in the 0.4-2.6 micrometer range. These powders were then included in water ice particles, sublimated under vacuum, in order to produce a hyperporous sample of hyperfine material. When grinded below one micrometre, the four materials studied (olivine, smectite, pyroxene and amorphous silica), show strong decrease of their absorption features together with a blueing of the spectra. This small grain degeneracy implies that surfaces covered by hyperfine grains should show only shallow absorption features if any. These two effects, decrease of band depth and spectral blueing, appear magnified when the grains are incorporated in the hyperporous residue. We interpret the distinct behaviour between hyperporous and more compact surfaces by the distancing of individual grains and a decrease in the size of the elemental scatterers. This work implies that hyperfine grains are unabundant at the surfaces of S- or V-type asteroids, and that the blue nature of B-type may be related to a physical effect rather than a compositional effect.