Space weathering simulations through controlled growth of iron nanoparticles on olivine

Airless planetary bodies are directly exposed to space weathering. The main spectral effects of space weathering are darkening, reduction in intensity of silicate mineral absorption bands, and an increase in the spectral slope towards longer wavelengths (reddening). Production of nanophase metallic...

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Published in:arXiv.org 2014-05
Main Authors: Kohout, T, Čuda, J, Filip, J, Britt, D, Bradley, T, Tuček, J, Skála, R, Kletetschka, G, Kašlík, J, Malina, O, Šišková, K, Zbořil, R
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Language:English
Subjects:
Absorption spectra
Computer simulation
Darkening
Heat treatment
Iron
Nanoparticles
Olivine
Reduction
Space weathering
Trends
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creator Kohout, T
Čuda, J
Filip, J
Britt, D
Bradley, T
Tuček, J
Skála, R
Kletetschka, G
Kašlík, J
Malina, O
Šišková, K
Zbořil, R
description Airless planetary bodies are directly exposed to space weathering. The main spectral effects of space weathering are darkening, reduction in intensity of silicate mineral absorption bands, and an increase in the spectral slope towards longer wavelengths (reddening). Production of nanophase metallic iron (npFe\(^{0}\)) during space weathering plays major role in these spectral changes. A laboratory procedure for the controlled production of npFe\(^{0}\) in silicate mineral powders has been developed. The method is based on a two-step thermal treatment of low-iron olivine, first in ambient air and then in hydrogen atmosphere. Through this process, a series of olivine powder samples was prepared with varying amounts of npFe\(^{0}\) in the 7-20 nm size range. A logarithmic trend is observed between amount of npFe\(^{0}\) and darkening, reduction of 1 {\mu}m olivine absorption band, reddening, and 1 {\mu}m band width. Olivine with a population of physically larger npFe\(^{0}\) particles follows spectral trends similar to other samples, except for the reddening trend. This is interpreted as the larger, ~40-50 nm sized, npFe\(^{0}\) particles do not contribute to the spectral slope change as efficiently as the smaller npFe\(^{0}\) fraction. A linear trend is observed between the amount of npFe\(^{0}\) and 1 {\mu}m band center position, most likely caused by Fe\(^{2+}\) disassociation from olivine structure into npFe\(^{0}\) particles.
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subjects Absorption spectra
Computer simulation
Darkening
Heat treatment
Iron
Nanoparticles
Olivine
Reduction
Space weathering
Trends
title Space weathering simulations through controlled growth of iron nanoparticles on olivine
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