Peering into the dark side: magnesium lines establish a massive neutron star in PSR J2215+5135

TL;DR

This study uses optical spectroscopy and photometry of the binary MSP PSR J2215+5135 to measure a neutron star mass of about 2.27 solar masses, challenging some neutron star interior models.

Contribution

It provides the first detailed analysis of irradiation effects on radial velocity measurements and derives a precise neutron star mass using a physical model of the companion star.

Findings

Neutron star mass estimated at 2.27 solar masses.

Radial velocity measurements depend on spectral lines used.

Irradiation effects significantly influence mass measurements.

Abstract

New millisecond pulsars (MSPs) in compact binaries provide a good opportunity to search for the most massive neutron stars. Their main-sequence companion stars are often strongly irradiated by the pulsar, displacing the effective center of light from their barycenter and making mass measurements uncertain. We present a series of optical spectroscopic and photometric observations of PSR J2215+5135, a "redback" binary MSP in a 4.14 hr orbit, and measure a drastic temperature contrast between the dark/cold (T$_\mathrm{N}$=5660$^{+260}_{-380}$ K) and bright/hot (T$_\mathrm{D}$=8080$^{+470}_{-280}$ K) sides of the companion star. We find that the radial velocities depend systematically on the atmospheric absorption lines used to measure them. Namely, the semi-amplitude of the radial velocity curve of J2215 measured with magnesium triplet lines is systematically higher than that measured with hydrogen Balmer lines, by 10%. We interpret this as a consequence of strong irradiation, whereby metallic lines dominate the dark side of the companion (which moves faster) and Balmer lines trace its bright (slower) side. Further, using a physical model of an irradiated star to fit simultaneously the two-species radial velocity curves and the three-band light curves, we find a center-of-mass velocity of K$_2$=412.3$\pm$5.0 km s$^{-1}$ and an orbital inclination i=63.9$^\circ$$^{+2.4}_{-2.7}$. Our model is able to reproduce the observed fluxes and velocities without invoking irradiation by an extended source. We measure masses of M$_1$=2.27$^{+0.17}_{-0.15}$ M$_\odot$ and M$_2$=0.33$^{+0.03}_{-0.02}$ M$_\odot$ for the neutron star and the companion star, respectively. If confirmed, such a massive pulsar would rule out some of the proposed equations of state for the neutron star interior.