Direct imaging of an ultracool substellar companion to the exoplanet host star HD 4113A

TL;DR

This study presents the first direct images of a cold brown dwarf companion to the exoplanet host star HD 4113A, combining imaging and radial velocity data to analyze its properties and orbital dynamics.

Contribution

It provides the first direct imaging of a cold brown dwarf around HD 4113A and combines this with long-term radial velocity data for comprehensive orbital analysis.

Findings

Brown dwarf HD 4113C is a late-T type with an estimated mass of 66±5 M_J.

The brown dwarf shows strong methane absorption and has an effective temperature of 500-600K.

Orbital analysis suggests the brown dwarf has a moderate eccentricity of 0.44±0.08.

Abstract

Using high-contrast imaging with the SPHERE instrument at the VLT, we report the first images of a cold brown dwarf companion to the exoplanet host star HD4113A. The brown dwarf HD4113C is part of a complex dynamical system consisting of a giant planet, stellar host and a known wide M-dwarf companion. Its separation of $535\pm3$mas and H-band contrast of $13.35\pm0.10$mag correspond to a projected separation of 22AU and an isochronal mass estimate of $36\pm5$M$_J$ based on COND models. The companion shows strong methane absorption, and through atmospheric model fitting we estimate a surface gravity of $\log g$=5 and an effective temperature of ~500-600K. A comparison of its spectrum with observed T dwarfs indicates a late-T spectral type, with a T9 object providing the best match. By combining the observed astrometry from the imaging data with 27 years of radial velocities, we use orbital fitting to constrain its orbital and physical parameters, as well as update those of the planet HD4113Ab, discovered by previous radial velocity measurements. The data suggest a dynamical mass of $66\pm5$M$_J$ and moderate eccentricity of $0.44\pm0.08$ for the brown dwarf. This mass estimate appears to conflict with the isochronal estimate and that of similar objects, which may be caused by the newly detected object being an unresolved binary brown dwarf system or the presence of an additional object in the system. Through dynamical simulations we show that the planet may undergo strong Lidov-Kozai cycles, raising the possibility that it formed on a quasi-circular orbit and gained its currently observed high eccentricity through interactions with the brown dwarf. Follow-up observations combining radial velocities, direct imaging and Gaia astrometry will be crucial to precisely constrain the dynamical mass of the brown dwarf and allow for in-depth comparison with evolutionary and atmospheric models.