Publication
Names
  • S. De Angelis
  • F. Tosi
  • C. Carli
  • S. Potin
  • P. Beck
  • O. Brissaud
  • B. Schmitt
  • G. Piccioni
  • M. C. De Sanctis
  • F. Capaccioni
Title
Temperature-dependent, VIS-NIR reflectance spectroscopy of sodium sulfates
Abstract
Hydrated sodium sulfates have been suggested to be present in variable amounts in Solar System objects such as Mars and Europa, among the possible others. The presence of these hydrated species is related to current/past aqueous environments, thus has an importance regarding the potential habitability of planetary objects. In this study, we analyzed anhydrous sodium sulfate (thénardite) and the hydrated sodium sulfate (mirabilite) by means of visible-infrared reflectance spectroscopy in the 0.4–5 μm spectral range, at different low temperatures between 80 and 298 K. Each mineral has been analyzed in three different grain sizes, between 36 and 150 μm. The anhydrous compound, th´enardite, is characterized by a nearly flat spectrum in the visible and near IR up to 2.6 μm, while in the 3–4 μm region, the spectrum shows a few weak features due to H2O and $SO_4^{2-}$ overtones/combinations. The first strong $SO_4^{2-}$ overtone is visible at 4.6 μm. Spectra of mirabilite are substantially characterized by H2O absorption features in the 1–3 μm region, and by sulfate overtone/combination bands occurring at 3.8 and 4.7 μm. A weak feature appearing at 2.18 μm is also putatively attributed to the sulfate ion. The bands show changes as a function of temperature. The hydration absorption features in mirabilite show the strongest dependence with temperature, both in terms of shift in position and change of spectral shape. Bands at 3.1–3.24 μm in thénardite, as well as absorption features located at 1.78 and 2.47 μm in mirabilite, could be used as diagnostic proxies for the detection of these two minerals on planetary bodies.
Keywords
spectroscopy, bidirectional reflectance spectra, visible, near-IR, grain size, low temperature, band depth, band with, band position, band intensity, minerals, thénardite, mirabilite
Content
spectral data, spectral data use, planetary sciences
Year
2021
Journal
Icarus
Volume
357
Number
114165
Pages
1 - 14
Pages number
14
Document type
article
Publication state
published