The MUSCLES Treasury Survey III: X-ray to Infrared Spectra of 11 M and K Stars Hosting Planets

TL;DR

This paper provides a comprehensive catalog of spectral energy distributions for 11 M and K dwarf stars, analyzing their UV to IR spectra to understand stellar radiation impacts on planetary atmospheres and photodissociation processes.

Contribution

It offers the first detailed, multi-wavelength SEDs for these stars, including reconstructed Lyα emission and UV continuum, aiding exoplanet atmospheric studies.

Findings

Photodissociation rates vary by over an order of magnitude among stars.

UV flux regions drive molecule dissociation differently for M and K stars.

Detected UV continuum in over half of the stars, influencing atmospheric chemistry.

Abstract

We present a catalog of panchromatic spectral energy distributions (SEDs) for 7 M and 4 K dwarf stars that span X-ray to infrared wavelengths (5 {\AA} - 5.5 {\mu}m). These SEDs are composites of Chandra or XMM-Newton data from 5 - ~50 {\AA}, a plasma emission model from ~50 - 100 {\AA}, broadband empirical estimates from 100 - 1170 {\AA}, HST data from 1170 - 5700 {\AA}, including a reconstruction of stellar Ly{\alpha} emission at 1215.67 {\AA}, and a PHOENIX model spectrum from 5700 - 55000 {\AA}. Using these SEDs, we computed the photodissociation rates of several molecules prevalent in planetary atmospheres when exposed to each star's unattenuated flux ("unshielded" photodissociation rates) and found that rates differ among stars by over an order of magnitude for most molecules. In general, the same spectral regions drive unshielded photodissociations both for the minimally and maximally FUV active stars. However, for ozone visible flux drives dissociation for the M stars whereas NUV flux drives dissociation for the K stars. We also searched for an FUV continuum in the assembled SEDs and detected it in 5/11 stars, where it contributes around 10% of the flux in the range spanned by the continuum bands. An ultraviolet continuum shape is resolved for the star {\epsilon} Eri that shows an edge likely attributable to Si II recombination. The 11 SEDs presented in this paper, available online through the Mikulski Archive for Space Telescopes, will be valuable for vetting stellar upper-atmosphere emission models and simulating photochemistry in exoplanet atmospheres.