| Issue |
A&A
Volume 483, Number 2, May IV 2008
|
|
|---|---|---|
| Page(s) | 661 - 672 | |
| Section | Catalogs and data | |
| DOI | https://doi.org/10.1051/0004-6361:20078468 | |
| Published online | 11 March 2008 | |
Optical properties of silicon carbide for astrophysical applications*
I. New laboratory infrared reflectance spectra and optical constants
1
Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA 91109, USA e-mail: Karly.M.Pitman@jpl.nasa.gov
2
Department of Earth and Planetary Sciences, Washington University, St. Louis, MO 63130, USA e-mail: hofmeist@levee.wustl.edu
3
Department of Physics and Astronomy, University of Missouri-Columbia, Columbia, MO 65211, USA e-mail: abcp68@mizzou.edu; speckan@missouri.edu
Received:
10
August
2007
Accepted:
1
March
2008
Aims. The SiC optical constants are fundamental inputs for radiative transfer (RT) models of astrophysical dust environments. However, previously published values contain errors and do not adequately represent the bulk physical properties of the cubic (β) SiC polytype usually found around carbon stars. We provide new, uncompromised optical constants for β- and α-SiC derived from single-crystal reflectance spectra and investigate quantitatively (i) whether there is any difference between α- and β-SiC that can be seen in infrared (IR) spectra and optical functions and (ii) whether weak features from λ ~ 12.5-13.0 μm need to be fitted.
Methods. We measured mid- and far-IR
reflectance spectra for two samples of 3C (β-)SiC and four samples of
6H (α-)SiC. For the latter group, we acquired polarized data
(
, 
orientations). We calculated the
real and imaginary parts of the complex refractive index
and the ideal absorption coefficients via
classical dispersion fits to our reflectance spectra.
Results. We find that β-SiC and 
α-SiC have
almost identical optical functions but that
and 
for 
α-SiC
are shifted to lower frequency. Peak positions determined for both
3C (β-) and 6H (α-)SiC polytypes agree with Raman
measurements and show that a systematic error of 4 cm-1 exists
in previously published IR analyses, attributable to
inadequate resolution of older instruments for the steep, sharp modes of SiC.
Weak modes are present for samples with impurities. Our
calculated absorption coefficients are much higher than laboratory
measurements. Whereas astrophysical dust grain sizes remain fairly
unconstrained, SiC grains larger than about 1 μm in diameter
will be opaque at frequencies near the peak center.
Conclusions. Previous optical constants for SiC do not reflect the true bulk properties, and they are only valid for a narrow grain size range. The new optical constants presented here will allow narrow constraints to be placed on the grain size and shape distribution that dominate in astrophysical environments.
Key words: methods: laboratory / stars: carbon / stars: circumstellar matter / ISM: dust, extinction
© ESO, 2008
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