Near-infrared spectro-interferometry of three OH/IR Stars with the VLTI/AMBER instrument

TL;DR

This study uses near-infrared spectro-interferometry with VLTI/AMBER to analyze the molecular and dust environments of three OH/IR stars, revealing details about their size, dust envelopes, and mass-loss during the superwind phase.

Contribution

First near-infrared interferometric measurements of OH/IR stars' dust and molecular environments, providing insights into the superwind phase of late-stage stellar evolution.

Findings

Central stellar diameters between 3.2 and 5.4 mas.

Dust envelope sizes between 17.1 and 25.2 mas.

Dust envelopes have higher optical depth than Mira stars.

Abstract

We investigate the molecular and dusty environment of OH/IR stars in order to characterize the mass-loss process during the tip-AGB superwind phase. Employing the AMBER instrument at the VLT Interferometer we obtained near-infrared H- and K-band spectro-interferometric observations of the three OH/IR stars IRAS 13479-5436, IRAS 14086-6907 and IRAS 17020-5254 with a spectral resolution of about 35. We use a two-component geometrical model, consisting of a uniform disk and a Gaussian disk, to obtain characteristic angular sizes of the central stellar sources and their dust envelopes, as well as the flux ratios between these components. Angular uniform disk diameters of the three central components of the objects above have values between 3.2 mas and 5.4 mas. For their dust envelopes, we find FWHM values between 17.1 mas and 25.2 mas. According to distance estimates from the literature, the central stellar components have radii between 900 R_sun and 1400 R_sun, while their dust envelopes reach FWHM values between 9000 R_sun and 13000 R_sun. The visibility functions of all three sources exhibit wavelength variations that resemble those of earlier VLTI/AMBER observations of semi-regular and Mira variable AGB stars. These are interpreted as characteristic of atmospheric molecular layers lying above the photosphere. We also find that the dust envelopes have a clearly larger optical depth than those known for Mira stars. We interpret this as an expected result of the "superwind" phase, the final 10 000 to 30 000 years of AGB-evolution, when the mass-loss rate increases by a factor of 10-100. By their different optical depths, the three dust shells studied here may represent different stages of the "superwind" and different initial masses.