New infrared spectral indices of luminous cold stars: from early K to   M-types

Maria Messineo (University of Science; Technology of China); Donald; F. Figer (Rochester Institute of Technology); Rolf-Peter Kudritzki; (University of Hawaii); Qingfeng Zhu (University of Science; Technology of; China); Karl M. Menten (Max-Planck-Institut fuer Radioastronomie); Valentin; D. Ivanov (European Southern Observatory); C.-H. Rosie Chen; (Max-Planck-Institut fuer Radioastronomie)

arXiv:2107.03707·astro-ph.SR·October 20, 2021

New infrared spectral indices of luminous cold stars: from early K to M-types

Maria Messineo (University of Science, Technology of China), Donald, F. Figer (Rochester Institute of Technology), Rolf-Peter Kudritzki, (University of Hawaii), Qingfeng Zhu (University of Science, Technology of, China), Karl M. Menten (Max-Planck-Institut fuer Radioastronomie)

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TL;DR

This paper introduces new infrared spectral indices for classifying luminous cold stars, especially red supergiants, using low-resolution spectra to distinguish them from giants and AGB stars in obscured regions.

Contribution

The study develops and validates new infrared spectral indices that effectively differentiate red supergiants from giants and AGB stars at low spectral resolution.

Findings

01

CO equivalent width >45 Å indicates late-type RSGs.

02

Mg I line helps distinguish RSGs from giants.

03

Certain molecular features identify Mira and S-type AGBs.

Abstract

We present infrared spectral indices (1.0-2.3 um) of Galactic late-type giants and red supergiants (RSGs). We used existing and new spectra obtained at resolution power R=2000 with SpeX on the IRTF telescope. While a large CO equivalent width (EW), at 2.29 um ([CO, 2.29]>45 AA) is a typical signature of RSGs later than spectral type M0, [CO] of K-type RSGs and giants are similar. In the [CO, 2.29] versus [Mg I, 1.71] diagram, RSGs of all spectral types can be distinguished from red giants, because the Mg I line weakens with increasing temperature and decreasing gravity. We find several lines that vary with luminosity, but not temperature: Si I (1.59 um), Sr (1.033 um), Fe+Cr+Si+CN (1.16 um), Fe+Ti (1.185 um), Fe+Ti (1.196 um), Ti+Ca (1.28 um), and Mn (1.29 um). Good markers of CN enhancement are the Fe+Si+CN line at 1.087 um and CN line at 1.093 um. Using these lines, at the resolution…

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