Chemical analysis of CH stars - I: atmospheric parameters and elemental abundances

TL;DR

This study provides detailed chemical compositions and atmospheric parameters for a sample of CH stars using high-resolution spectra, revealing heavy element enhancement patterns and contributions from nucleosynthesis processes.

Contribution

First detailed high-resolution spectral analysis of CH stars including atmospheric parameters and elemental abundances, with insights into s- and r-process contributions.

Findings

Heavy element enhancements observed in most CH stars.

Wide range of stellar temperatures and metallicities estimated.

First abundance analysis for HD 188650 based on high-resolution data.

Abstract

Results from high-resolution spectral analyses of a selected sample of CH stars are presented. Detailed chemical composition studies of these objects, which could reveal abundance patterns that in turn provide information regarding nucleosynthesis and evolutionary status, are scarce in the literature. We conducted detailed chemical composition studies for these objects based on high resolution (R ~ 42000) spectra. The spectra were taken from the ELODIE archive and cover the wavelength range from 3900 to 6800 A, in the wavelength range. We estimated the stellar atmospheric parameters, the effective temperature Teff, the surface gravity log g, and metallicity [Fe/H] from Local thermodynamic equilibrium analyses using model atmospheres. Estimated temperatures of these objects cover a wide range from 4550 K to 6030 K, the surface gravity from 1.8 to 3.8 and metallicity from -0.18 to -1.4. We report updates on elemental abundances for several heavy elements and present estimates of abundance ratios of Sr, Y, Zr, Ba, La, Ce, Pr, Nd, Sm, Eu and Dy with respect to Fe. For the object HD 188650 we present the first abundance analyses results based on a high resolution spectrum. Enhancements of heavy elements relative to Fe, that are characteristic of CH stars are evident from our analyses for most of the objects. A parametric model based study is performed to understand the relative contributions from the s- and r-processes to the abundances of the heavy elements.