Star-disk interaction in the T Tauri star V2129 Oph: An evolving accretion-ejection structure

TL;DR

This study investigates the magnetic interactions and accretion-ejection dynamics of the young T Tauri star V2129 Oph over a decade, revealing variability in accretion structures and magnetic topology on short timescales.

Contribution

It provides a detailed time series analysis of V2129 Oph, showing evolving accretion-ejection structures and magnetic field configurations in a young stellar object.

Findings

Magnetospheric accretion variability with a ~6.0d period

Detection of an 8.5d period possibly related to outer disk structures

Accretion-ejection dynamics change significantly over a few years

Abstract

Classical T Tauri stars are young low-mass systems still accreting material from their disks. These systems are dynamic on timescales of hours to years. The observed variability can help us infer the physical processes that occur in the circumstellar environment. We aim at understanding the dynamics of the magnetic interaction between the star and the inner accretion disk in young stellar objects. We present the case of the young stellar system V2129 Oph, which is a well-known T Tauri star. We performed a time series analysis of this star using high-resolution spectroscopic data at optical and infrared wavelengths from CFHT/ESPaDOnS, ESO/HARPS and CFHT/SPIRou. The new data sets allowed us to characterize the accretion-ejection structure in this system and to investigate its evolution over a timescale of a decade via comparisons to previous observational data. We measure radial velocity variations and recover a stellar rotation period of 6.53d. However, we do not recover the stellar rotation period in the variability of various circumstellar lines, such as H$\alpha$ and H$\beta$ in the optical or HeI 1083nm and Pa$\beta$ in the infrared. Instead, we show that the optical and infrared line profile variations are consistent with a magnetospheric accretion scenario that shows variability with a period of about 6.0d, shorter than the stellar rotation period. Additionally, we find a period of 8.5d in H$\alpha$ and H$\beta$ lines, probably due to a structure located beyond the corotation radius, at a distance of 0.09au. We investigate whether this could be accounted for by a wind component, twisted or multiple accretion funnel flows, or an external disturbance in the inner disk. We conclude that the dynamics of the accretion-ejection process can vary significantly on a timescale of just a few years, presumably reflecting the evolving magnetic field topology at the stellar surface.