Publication
Reference
Rubino Stefano, Potin Sandra, Lantz Cateline, Baklouti Donia, Beck Pierre, Brissaud Olivier, Leroux Hugues, Quirico Eric, Schmitt Bernard, Borondics Ferenc, Brunetto Rosario (2022). Geometry induced bias in the remote near-IR identification of phyllosilicates on space weathered bodies. Icarus, 376, 114887.
Names
  • Stefano Rubino
  • Sandra Potin
  • Cateline Lantz
  • Donia Baklouti
  • Pierre Beck
  • Olivier Brissaud
  • Hugues Leroux
  • Eric Quirico
  • Bernard Schmitt
  • Ferenc Borondics
  • Rosario Brunetto
Article and keywords
Title
Geometry induced bias in the remote near-IR identification of phyllosilicates on space weathered bodies
Abstract
Sample return missions Hayabusa2 (JAXA) and OSIRIS-REx (NASA) found evidence of hydrated silicates on the surface of C and B-type asteroids Ryugu and Bennu. This detection relied on the study of the 2.7 microns OH-stretching spectral feature revealed from remote sensing observations of the asteroids' surfaces. Laboratory studies simulating the effects of space weathering (SpWe) on primitive bodies have shown that the feature's position, considered as the wavelength of the band minimum, can vary under ion implantation, shifting towards longer wavelengths for implanted surfaces. Since SpWe is a surface process, we investigated how the geometry of observation can affect the hydration feature on space weathered surfaces. Here, we report new laboratory Reflectance Factors (REFF) measurements on pristine and ion-bombarded phyllosilicate pellets, to monitor the evolution of the 2.7 microns feature with varying observation geometry. We found that, as we approach specular reflection, the feature's position for He+ bombarded surfaces shifts towards longer wavelengths. We interpret that the spectral shift is due to chemical and physical changes induced by ion implantation in the first hundreds of nanometers of our phyllosilicate pellets. The diversity in the observed amplitude of the shift means that different competing effects are dominating at different optical configurations, mainly volume and surface scattering. The effects of the ion-implanted matter are especially visible when measuring in near-specular conditions, where the specular component (more sensible to the very top surface (implanted layer) of the sample)dominates - hence the larger shift measured. Our results indicate that the geometry of observation can induce a certain bias in the interpretation of remote sensing data from space-weathered bodies.
Keywords
Spectroscopy, bidirectional reflection, BRDF, band position, band width, band intensity, mineral
Content
BRDF data
Year
2022
Journal
Icarus
Volume
376
Pages
114887
Document type
article
Publication state
published
Doi
10.1016/j.icarus.2022.114887
Identifiers