The far-ultraviolet spectra of two hot PG1159 stars

TL;DR

This study analyzes the far-ultraviolet spectra of two extremely hot PG1159 stars to determine their surface element abundances, providing insights into stellar evolution and nucleosynthesis in post-AGB stars.

Contribution

It presents the first detailed abundance analysis of two very hot PG1159 stars using far-ultraviolet spectroscopy and non-LTE models, revising previous abundance estimates and confirming stellar evolution predictions.

Findings

Confirmed previous abundances for some elements.

Revised sulfur abundance to solar levels.

First-time determination of Na, Al, and Cl abundances.

Abstract

PG1159 stars are hot, hydrogen-deficient (pre-) white dwarfs with atmospheres mainly composed of helium, carbon, and oxygen. The unusual surface chemistry is the result of a late helium-shell flash. Observed element abundances enable us to test stellar evolution models quantitatively with respect to their nucleosynthesis products formed near the helium-burning shell of the progenitor asymptotic giant branch stars. Because of the high effective temperatures (Teff), abundance determinations require ultraviolet spectroscopy and non-local thermodynamic equilibrium model atmosphere analyses. Up to now, we have presented results for the prototype of this spectral class and two cooler members (Teff in the range 85,000-140,000 K). Here we report on the results for two even hotter stars (PG1520+525 and PG1144+005, both with Teff = 150,000 K) which are the only two objects in this temperature-gravity region for which useful far-ultraviolet spectra are available, and revisit the prototype star. Previous results on the abundances of some species are confirmed, while results on others (Si, P, S) are revised. In particular, a solar abundance of sulphur is measured in contrast to earlier claims of a strong S deficiency that contradicted stellar evolution models. For the first time, we assess the abundances of Na, Al, and Cl with newly constructed non-LTE model atoms. Besides the main constituents (He, C, O), we determine the abundances (or upper limits) of N, F, Ne, Na, Al, Si, P, S, Cl, Ar, and Fe. Generally, good agreement with stellar models is found.