Analysis of physical processes in eruptive YSOs with near infrared spectra and multi-wavelength light curves

TL;DR

This study investigates the physical mechanisms behind eruptive events in young stellar objects using near-infrared spectra and multi-wavelength light curves, revealing dominant accretion modes and variability patterns.

Contribution

It combines spectroscopic and photometric data to distinguish accretion-driven from extinction-driven variability in eruptive YSOs, highlighting the prevalence of magnetically controlled accretion.

Findings

Magnetically controlled accretion dominates in most eruptive YSOs.

Long-duration eruptions often show boundary layer accretion signatures.

Amplitude ratios in different wavelengths help differentiate variability causes.

Abstract

The decade-long Vista Variables in the Via Lactea (VVV) survey has detected numerous highly variable young stellar objects (YSOs). We present a study of 61 highly variable VVV YSOs ($\Delta K_s$ = 1-5 mag), combining near infrared spectra from Magellan and VLT with VVV and NEOWISE light curves to investigate physical mechanisms behind eruptive events. Most sources are spectroscopically confirmed as eruptive variables (typically Class I YSOs) but variable extinction is also seen. Among them, magnetically controlled accretion, identified by H{\sc i} recombination emission (usually accompanied by CO emission), is observed in 46 YSOs. Boundary layer accretion, associated with FU Ori-like outbursts identified by CO overtone and H$_2$O absorption, is observed only in longer duration events ($\ge$5 yr total duration). However, even in long duration events, the magnetically controlled accretion mode predominates, with amplitudes similar to the boundary layer mode. Shorter (100-700 days) eruptive events usually have lower amplitudes and these events are generally either periodic accretors or multiple timescale events, wherein large photometric changes occur on timescales of weeks and years. We find that the ratio of amplitudes in $K_s$ and $W2$ can distinguish between variable accretion and variable extinction. Several YSOs are periodic or quasi-periodic variables. We identify examples of periodic accretors and extinction-driven periodicity among them (with periods up to 5 yr) though more data are needed to classify some cases. The data suggest that dynamic interactions with a companion may control the accretion rate in a substantial proportion of eruptive systems, although star-disc interactions should also be considered.