A spectroscopic multiplicity survey of Galactic Wolf-Rayet stars: II. The northern WNE sequence

TL;DR

This study investigates the multiplicity properties of Galactic Wolf-Rayet stars, specifically the WNE subtype, using spectroscopic data to determine binary fractions and period distributions, revealing differences from other WR types and implications for stellar evolution.

Contribution

It provides the first detailed multiplicity analysis of the northern WNE Wolf-Rayet stars, including intrinsic binary fraction and period distribution parameters, using a Bayesian Monte Carlo approach.

Findings

Observed WNE binary fraction is 44%

Intrinsic WNE binary fraction is approximately 56%

WNE and WC populations show different period distributions

Abstract

Most massive stars reside in multiple systems that will interact over the course of their lifetime. Classical Wolf-Rayet (WR) stars represent the final end stages of stellar evolution at the upper-mass end. As part of a homogeneous, magnitude-limited ($V\leq12$) spectroscopic survey of northern Galactic WR stars, this paper aims to establish the observed and intrinsic multiplicity properties of the early-type nitrogen-rich WR population (WNE). We obtained high-resolution spectroscopic time series of the complete magnitude-limited sample of 16 WNE stars observable with the 1.2 m Mercator telescope at La Palma, typically providing a time base of about two to eight years. We measured relative radial velocities (RVs) using cross-correlation and used RV variations to flag binary candidates. Adopting a peak-to-peak RV variability threshold of 50 km/s as a criterion found an observed multiplicity fraction of 0.44$\pm$0.12. Using an updated Monte Carlo method with a Bayesian framework, we calculated the three-dimensional likelihood for the intrinsic binary fraction, the maximum period, and the power-law index for the period distribution for the WNE population. We also re-derived multiplicity parameters for the Galactic WC population. We found an intrinsic multiplicity fraction of $0.56\substack{+0.20 \\ -0.15}$ for the parent WNE population. For the Galactic WC population, we re-derive an intrinsic multiplicity fraction of $0.96\substack{+0.04 \\ -0.22}$. The derived multiplicity parameters for the WNE population are quite similar to those derived for main-sequence O binaries but differ from those of the WC population. The significant shift in the WC period distribution towards longer periods is too large to be explained via expansion of the orbit due to stellar winds, and we discuss possible implications of our results.