Spectroscopic survey of faint planetary-nebula nuclei VI. Seventeen hydrogen-rich central stars

TL;DR

This study spectroscopically analyzed 17 hydrogen-rich central stars of planetary nebulae, deriving their physical parameters, discovering a rare hot white dwarf, and examining their variability and spectral energy distributions to understand their evolutionary stages.

Contribution

First-time NLTE atmospheric analysis of 16 central stars, increasing the sample size by 20%, and identifying unique objects like a very hot DA white dwarf and a high-mass sdOB star.

Findings

Discovered a hot DA white dwarf with over 100,000 K temperature.

Identified a high-gravity sdOB star with a mass of 0.70 solar masses.

Found no significant photometric variability in the sample.

Abstract

We present an analysis of 17 H-rich central stars of planetary nebulae (PNe) observed in our spectroscopic survey of nuclei of faint Galactic PNe carried out at the 10-m Hobby-Eberly Telescope. Our sample includes ten O(H) stars, four DAO white dwarfs (WDs), two DA WDs, and one sdOB star. The spectra were analyzed by means of NLTE model atmospheres, allowing us to derive the effective temperatures, surface gravities, and He abundances of the central stars. Sixteen of them were analyzed for the first time, increasing the number of hot H-rich central stars with parameters obtained through NLTE atmospheric modeling by approximately 20%. We highlight a rare hot DA WD central star, Abell 24, which has a $T_\mathrm{eff}$ likely in excess of 100kK, as well as the unusually high gravity mass of $0.70 \pm 0.05 \mathrm{M}_\odot$ for the sdOB star Pa 3, which is significantly higher than the canonical extreme horizontal-branch star mass of $\approx 0.48\,\mathrm{M}_{\odot}$. By investigating Zwicky Transient Facility light curves, which were available for our 15 northern objects, we found none of them show a periodic photometric variability larger than a few hundredths of a magnitude. This could indicate that our sample mainly represents the hottest phase during the canonical evolution of a single star when transitioning from an asymptotic giant branch star into a WD. We also examined the spectral energy distributions, detecting an infrared excess in six of the objects, which could be due to a late-type companion or to hot ($\approx 10^3$ K) and\or cool ($\approx 100$ K) dust. We confirm previous findings that spectroscopic distances are generally higher than found through Gaia astrometry, a discrepancy that deserves to be investigated systematically.