Multi-frequency high spectral resolution observations of HCN toward the circumstellar envelope of Y CVn

TL;DR

This study presents high spectral resolution observations of HCN in the circumstellar envelope of Y CVn, revealing detailed molecular excitation, velocity structures, and isotopic ratios, advancing understanding of AGB star chemistry and dynamics.

Contribution

It provides the first comprehensive multi-frequency high-resolution analysis of HCN lines in Y CVn, including vibrational and rotational states, and models the physical conditions of its circumstellar envelope.

Findings

HCN lines involve high energy levels up to ~3900 K.

Gas accelerates from photosphere to terminal velocity, with evidence of higher velocities beyond 3 stellar radii.

HCN is out of LTE, with a total column density of ~2.1-3.5 x 10^{18} cm^{-2}.

Abstract

High spectral resolution observations toward the low mass-loss rate C-rich, J-type AGB star Y CVn have been carried out at 7.5, 13.1 and 14.0 um with SOFIA/EXES and IRTF/TEXES. Around 130 HCN and H13CN lines of bands v2, 2v2, 2v2-v2, 3v2-2v2, 3v2-v2, and 4v2-2v2 have been identified involving lower levels with energies up to ~3900 K. These lines have been complemented with the pure rotational lines J=1-0 and 3-2 of the vibrational states up to 2v2 acquired with the IRAM 30 m telescope, and with the continuum taken with ISO. We have analyzed the data with a ro-vibrational diagram and a code which models the absorption and emission of the circumstellar envelope of an AGB star. The continuum is produced by the star with a small contribution from dust grains comprising warm to hot SiC and cold amorphous carbon. The HCN abundance distribution seems to be anisotropic. The ejected gas is accelerated up to the terminal velocity (~8 km/s) from the photosphere to ~3R* but there is evidence of higher velocities (>9-10 km/s) beyond this region. In the vicinity of Y CVn, the line widths are as high as ~10 km/s, which implies a maximum turbulent velocity of 6 km/s or the existence of other physical mechanisms probably related to matter ejection that involve higher gas expansion velocities than expected. HCN is rotationally and vibrationally out of LTE throughout the whole envelope. A difference of about 1500 K in the rotational temperature at the photosphere is needed to explain the observations at 7.5 and 13-14 um. Our analysis finds a total HCN column density that ranges from ~2.1E+18 to 3.5E+18 cm^{-2}, an abundance with respect to H2 of 3.5E-05 to 1.3E-04, and a 12C/13C isotopic ratio of ~2.5 throughout the whole envelope.