Unveiling accretion in the massive YSO G033.3891. Spatial and kinematic constraints from the CO bandhead emission

TL;DR

This study uses high-resolution interferometry to spatially and kinematically resolve the innermost gaseous accretion disc around a massive young stellar object, revealing that gaseous emissions occur within the dust sublimation radius.

Contribution

First to spatially and kinematically resolve the inner gaseous accretion disc in a MYSO using CO bandhead emission with high-resolution interferometry.

Findings

Gaseous emissions are located within 5 au, inside the dust sublimation radius.

CO and Brγ emissions are confined within the dust sublimation radius.

The inner gaseous disc extends down to about 2 au from the star.

Abstract

The inner parts of the hot discs surrounding massive young stellar objects (MYSOs) are still barely explored due to observational limitations in terms of angular resolution, scarcity of diagnostic lines and the embedded and rare nature of these targets. We present the first K-band spectro-interferometric observations toward the MYSO G033.3891, which based on former kinematic evidence via the CO bandhead emission is known to host an accreting disc. Using the high spectral resolution mode (R$\sim$4000) of the GRAVITY/VLTI, we spatially resolve the emission of the inner dusty disc and the crucial gaseous interface between the star and the dusty disc. Using detailed modelling on the K-band dust continuum and tracers known to be associated with the ionised and molecular gaseous interface (Br$\gamma$, CO), we report on the smallest scales of accretion/ejection. The new observations in combination with our geometric and kinematic models employed to fit former high spectral resolution observations on the source (R$\sim$30,000; CRIRES/VLTI) allow us to constrain the size of the inner gaseous disc both spatially and kinematically via the CO overtone emission at only 2 au. Our models reveal that both Br$\gamma$ and CO emissions are located well within the dust sublimation radius (5~au) as traced by the hot 2.2~$\mu$m dust continuum. Our paper provides the first case study where the tiniest scales of gaseous accretion around the MYSO G033.3891 are probed both kinematically and spatially via the CO bandhead emission. This analysis of G033.3891 stands as only the second instance of such investigation within MYSOs, underscoring the gradual accumulation of knowledge regarding how massive young stars gain their mass, while further solidifying the disc nature of accretion at the smallest scales of MYSOs.