Shock excited far-infrared molecular emission around T Tau

TL;DR

This study presents the first complete far-infrared spectrum of T Tau, revealing shock-excited molecular emission from water, OH, and CO, indicating energetic outflows and shock processes in a compact region near the stars.

Contribution

It provides the first full far-infrared spectrum of T Tau and interprets the molecular emission as shock-excited, highlighting the role of stellar winds and UV radiation in the outflow region.

Findings

Detection of high-J CO, water, and OH emission lines.

Molecular emission originates from a compact, warm region (~300-900 K).

Water and OH are significantly overabundant compared to ambient gas.

Abstract

The first complete far-infrared spectrum of T Tau has been obtained with the LWS spectrometer on-board the Infrared Space Observatory, which detected strong emission from high-J (J=14-25) CO, para- and ortho-H2O and OH transitions over the wavelength range from 40 to 190 micron. Most of the observed molecular emission can be explained by a single emission region at T~300-900 K and n(H_2)~10^(5-6) cm^(-3),with a diameter of about 2-3 arcsec. This corresponds to a very compact region of 300-400 AU at the distance of 140 pc. An higher temperature component seems to be needed to explain the highest excitation CO and water lines. We derive a water abundance of 1-7x10^(-5) and an OH abundance of ~3x10^(-5) with respect to molecular hydrogen, implying water and OH enhancements by more than a factor of 10 with respect to the expected ambient gas abundance. The observed cooling in the various species amounts to 0.04 L(sun),comparable to the mechanical luminosity of the outflow, indicating that the stellar winds could be responsible of the line excitation through shocks. In order to explain the observed molecular cooling in T Tau in terms of C-type shock models, we hypothesise that the strong far-ultraviolet radiation field photodissociates water in favour of OH. This would explain the large overabundance of OH observed. The estimated relatively high density and compactness of the observed emission suggest that it originates from the shocks taking place at the base of the molecular outflow emission, in the region where the action of the stellar winds from the two stars of the binary system is important.