HD 156324: a tidally locked magnetic triple spectroscopic binary with a disrupted magnetosphere

TL;DR

HD 156324 is a unique tidally locked magnetic triple star system with a disrupted magnetosphere, showing unusual H-alpha emission and complex orbital dynamics, providing insights into stellar magnetism and binary interactions.

Contribution

This study reveals the first detailed analysis of a tidally locked magnetic triple system with a disrupted magnetosphere, highlighting the impact of stellar companions on magnetic and emission properties.

Findings

The primary star is tidally locked with a 1.58-day orbital period.

The system's orbit is circularized, indicating tidal synchronization.

The H-alpha emission morphology is atypical, likely due to the companion's influence.

Abstract

HD 156324 is an SB3 (B2V/B5V/B5V) system in the Sco OB4 association. The He-strong primary possesses both a strong magnetic field, and H$\alpha$ emission believed to originate in its Centrifugal Magnetosphere (CM). We analyse a large spectroscopic and high-resolution spectropolarimetric dataset. The radial velocities (RVs) indicate that the system is composed of two sub-systems, which we designate A and B. Period analysis of the RVs of the three components yields orbital periods $P_{\rm orb} = 1.5806(1)$~d for the Aa and Ab components, and 6.67(2)~d for the B component, a PGa star. Period analysis of the longitudinal magnetic field \bz~and H$\alpha$ equivalent widths, which should both be sensitive to the rotational period $P_{\rm rot}$ of the magnetic Aa component, both yield $\sim$1.58~d. Since $P_{\rm orb} = P_{\rm rot}$ Aa and Ab must be tidally locked. Consistent with this, the orbit is circularized, and the rotational and orbital inclinations are identical within uncertainty, as are the semi-major axis and the Kepler corotation radius. The star's H$\alpha$ emission morphology differs markedly from both theoretical and observational expectations in that there is only one, rather than two, emission peaks. We propose that this unusual morphology may be a consequence of modification of the gravitocentrifugal potential by the presence of the close stellar companion. We also obtain upper limits on the magnetic dipole strength $B_{\rm d}$ for the Ab and B components, respectively finding $B_{\rm d} < 2.6$~kG and $<0.7$~kG.