The close circumstellar environment of the semi-regular S-type star Pi^1 Gruis

TL;DR

This study uses high-resolution mid-infrared interferometry to characterize the dust and molecular shells around the S-type star Pi^1 Gruis, revealing a spherical dust shell and a molecular shell, with implications for binary interactions.

Contribution

First detailed interferometric modeling of Pi^1 Gruis's close environment, combining dust and molecular shells with radiative transfer fitting.

Findings

Dust shell located at 14 stellar radii with 700 K temperature.

Molecular shell extending up to 4.4 stellar radii with 1000 K.

No significant asymmetry detected on milliarcsecond scales.

Abstract

We study the close circumstellar environment of the nearby S-type star Pi^1 Gruis using high spatial-resolution, mid-infrared observations from the ESO/VLTI. Spectra and visibilities were obtained with the MIDI interferometer on the VLT Auxiliary Telescopes. The cool M5III giant Beta Gruis was used as bright primary calibrator, and a dedicated spectro-interferometric study was undertaken to determine its angular diameter accurately. The MIDI measurements were fitted with the 1D numerical radiative transfer code DUSTY to determine the dust shell parameters of Pi^1 Gruis. Taking into account the low spatial extension of the model in the 8-9 $\mu$m spectral band for the smallest projected baselines, we consider the possibility of a supplementary molecular shell. The MIDI visibility and phase data are mostly dominated by the spherical 21 mas (694 Rsol) central star, while the extended dusty environment is over-resolved even with the shortest baselines. No obvious departure from spherical symmetry is found on the milliarcsecond scale. The spectro-interferometric observations are well-fitted by an optically thin (tau(dust)<0.01 in the band) dust shell that is located at about 14 stellar radii with a typical temperature of 700 K and composed of 70% silicate and 30% of amorphous alumina grains. An optically thin (tau(mol)<0.1 in the N band) H2O+SiO molecular shell extending from the photosphere of the star up to 4.4 stellar radii with a typical temperature of 1000 K is added to the model to improve the fit in the 8-9 $\mu$m spectral band. We discuss the probable binary origin of asymmetries as revealed by millimetric observations.