Diagnosing FUor-like Sources: The Parameter Space of Viscously Heated Disks in the Optical and Near-IR

TL;DR

This paper models FUor-like young stellar objects by combining viscous and passive disk components, validating with observations, and identifying spectral diagnostics to understand accretion processes and disk dominance in optical and near-infrared spectra.

Contribution

The study introduces comprehensive models of FUor objects incorporating multiple emission components and explores spectral diagnostics based on brightness ratios to identify viscous accretion disks.

Findings

Brightness ratio η is key for identifying viscous disks.

Transition and dominance lines mark spectral and color-magnitude changes.

Higher accretion rates increase η and disk dominance.

Abstract

FU Ori type objects (FUors) are decades-long outbursts of accretion onto young stars that are strong enough to viscously heat disks so that the disk outshines the central star. We construct models for FUor objects by calculating emission components from a steady-state viscous accretion disk, a passively-heated dusty disk, magnetospheric accretion columns, and the stellar photosphere. We explore the parameter space of the accretion rate and stellar mass to investigate implications on the optical and near-infrared spectral energy distribution and spectral lines. The models are validated by fitting to multi-wavelength photometry of three confirmed FUor objects, FU Ori, V883 Ori and HBC 722 and then comparing the predicted spectrum to observed optical and infrared spectra. The brightness ratio between the viscous disk and the stellar photosphere, $\eta$, provides an important guide for identifying viscous accretion disks, with $\eta=1$ ("transition line") and $\eta=5$ ("sufficient dominance line") marking turning points in diagnostics, evaluated here in the near-infrared. These turning points indicate the emergence and complete development of FUor-characteristic strong CO absorption, weak metallic absorption, the triangular spectral continuum shape in the $H$-band, and location in color-magnitude diagrams. Lower stellar mass $M_*$ and higher accretion rate $\dot{M}$ lead to larger $\eta$; for $M_*=0.3~{\rm M_\odot}$, $\eta=1$ corresponds to $\dot{M}=2\times10^{-7}~{\rm M_\odot}/$yr and $\eta=5$ to $\dot{M}=6\times10^{-7}~{\rm M_\odot}/$yr. The sufficient dominance line also coincides with the expected accretion rate where accreting material directly reaches the star. We discuss implications of the models on extinction diagnostics, FUor brightening timescales, viscous disks during initial protostellar growth, and eruptive young stellar objects (YSO) associated with FUors.