IGRINS spectroscopy of Class I sources: IRAS 03445+3242 and IRAS 04239+2436

TL;DR

This study uses high-resolution IGRINS spectroscopy to analyze the hot and warm inner disks of two Class I protostars, revealing Keplerian disk features, complex line variations, and both hot and cold CO gas components.

Contribution

First high-resolution IR spectroscopic analysis of Class I sources with simultaneous H and K band coverage revealing disk structure and dynamics.

Findings

Detection of molecular and atomic emission lines indicating hot inner disks.

Evidence for Keplerian rotation in the disks from line profiles.

Observation of asymmetric line profile variations over different timescales.

Abstract

We have detected molecular and atomic line emission from the hot and warm disks of two Class I sources, IRAS 03445+3242 and IRAS 04239+2436 using the high resolution Immersion GRating INfrared Spectrograph (IGRINS). CO overtone band transitions and near-IR lines of Na I and Ca I, all in emission, trace the hot inner disk while CO rovibrational absorption spectra of the first overtone transition trace the warm gas within the inner few AU of the disk. The emission-line profiles for both sources show evidence for Keplerian disks. A thin Keplerian disk with power-law temperature and column density profiles with a projected rotational velocity of $\sim$60--75 km s$^{-1}$ and a gas temperature of $\sim$3500 K at the innermost annulus can reproduce the CO overtone band emission. Na I and Ca I emission lines also arise from this disk, but they show complicated line features possibly affected by photospheric absorption lines. Multi-epoch observations show asymmetric variations of the line profiles on one-year (CO overtone bandhead and atomic lines for IRAS 03445+3242) or on one-day (atomic lines for IRAS 04239+2436) time scales, implying non-axisymmetric features in disks. The narrow CO rovibrational absorption spectra ($v$=0$\rightarrow$2) indicate that both warm ($>$ 150 K) and cold ($\sim$20--30 K) CO gas are present along the line of sight to the inner disk. This study demonstrates the power of IGRINS as a tool for studies of the sub-AU scale hot and AU-scale warm protoplanetary disks with its simultaneous coverage of the full H and K bands with high spectral resolution ($R$= 45,000) allowing many aspects of the sources to be investigated at once.