Spatially resolved centrifugal magnetosphere caught in motion around the secondary component of $\rho$ Oph A

TL;DR

This study used high-resolution interferometry to spatially resolve and analyze the motion of a centrifugal magnetosphere around the magnetic star in the binary system $ ho$ Oph A, providing new insights into stellar magnetospheres.

Contribution

First direct spatially resolved observation of a centrifugal magnetosphere's motion around a magnetic star in a binary system.

Findings

Determined the 3D orbital solution and dynamical masses of the system.

Confirmed the alignment of the orbital and stellar rotation axes.

Detected the motion of the magnetospheric cloud and demonstrated prograde rotation.

Abstract

The recently discovered spectroscopic binary $\rho$ Oph A is a rare magnetic hot binary system composed of two early B-type stars, comprising a non-magnetic primary (Aa) and a slightly less massive magnetic secondary (Ab). Using near-IR interferometry, we aim to resolve the system's astrometric orbit. The high-spectral resolution VLTI/GRAVITY data also enables obtaining further information about the two stellar components, and about the centrifugal magnetosphere orbiting the magnetic star. We obtained a time-series of $K$-band interferometric data from VLTI/GRAVITY, and analyzed them with the geometrical model-fitting tool PMOIRED. The continuum was used to derive the relative astrometry and relative fluxes of the two components, leading to the astrometric orbital solution. Spectro-interferometry covering the Br$\gamma$ line was then used to obtain high-angular-resolution information about the dominant magnetospheric cloud in corotation with the magnetic Ab component. The combination of the astrometric orbital solution with the published radial velocities for both components led to a 3-dimensional orbital solution, dynamical masses, and a dynamical parallax, revealing a good agreement with previous estimates and confirming the previously inferred alignment of the orbital axis and the rotation axis of the Ab component, albeit at a much higher precision. Detailed analysis of the Br$\gamma$ spectrointerferometry then revealed the changing position of the magnetospheric cloud relative to the Ab component. Comparison to the location of the cloud predicted from $\rho$ Oph Ab's oblique rotator model and H$\alpha$ emission properties demonstrated excellent agreement. We are additionally able to demonstrate that the magnetic star exhibits prograde rotation. This represents the first time that the motion of a centrifugal magnetosphere has been detected in angularly resolved observations.