Rotational spectra of vibrationally excited AlO and TiO in oxygen rich stars

TL;DR

This study observed vibrationally excited AlO and TiO molecules in oxygen-rich stars using ALMA and SMA, revealing their high vibrational temperatures, spatial distribution near stars, and potential role in dust formation.

Contribution

It provides the first detailed observations of vibrationally excited AlO and TiO in evolved stars, including their spatial extent, abundance, and implications for dust seed formation.

Findings

High vibrational temperature (~1800 K) for AlO and TiO in R Dor

Most emission originates within ~2 stellar radii from the star

TiO likely exists in a rotating disk close to the star

Abstract

Rotational transitions in vibrationally excited AlO and TiO -- two possible precursors of dust -- were observed in the 300 GHz range (1 mm wavelength) towards the oxygen rich AGB stars R Dor and IK Tau with ALMA, and vibrationally excited AlO was observed towards the red supergiant VY CMa with the SMA. The $J=11 \to 10$ transition of TiO in the $v=1~{\rm{and}}~2$ levels, and the $N = 9 \to 8$ transition in the $v=2$ level of AlO were identified towards R Dor; the $J=11 \to 10$ line of TiO was identified in the $v=1$ level towards IK Tau; and two transitions in the $v=1~{\rm{and}}~2$ levels of AlO were identified towards VY CMa. The newly-derived high vibrational temperature of TiO and AlO in R Dor of $1800 \pm 200$ K, and prior measurements of the angular extent confirm that the majority of the emission is from a region within $\lesssim2R_{\star}$ of the central star. A full radiative transfer analysis of AlO in R Dor yielded a fractional abundance of $\sim$3% of the solar abundance of Al. From a similar analysis of TiO a fractional abundance of $\sim78$% of the solar abundance of Ti was found. The observations provide indirect evidence that TiO is present in a rotating disk close to the star. Further observations in the ground and excited vibrational levels are needed to determine whether AlO, TiO, and TiO$_2$ are seeds of the Al$_2$O$_3$ dust in R Dor, and perhaps in the gravitationally bound dust shells in other AGB stars with low mass loss rates.