Evolution of the dust in V4332 Sagittarii

TL;DR

This study tracks the evolution of dust formed after a stellar eruption in V4332 Sagittarii, revealing changes in dust composition and structure over time through infrared observations and modeling.

Contribution

It provides detailed observational evidence and modeling of dust formation and evolution in a stellar-merger event, highlighting the processes of condensation, annealing, and oxidation.

Findings

Significant changes in the 10 micron silicate feature over time.

Decrease of AlO in the outflow from 2003-2005 to 2014.

Presence of water vapor indicating ongoing chemical processes.

Abstract

An eruptive nova-like event took place in 1994 in the stellar-merger candidate V4332 Sgr. Following the eruption, dust consisting of refractory silicate rich dust grains containing a significant component of AlO bonding was formed sometime between 1998 and 2003. Observations using Spitzer between 2005 and 2009 show significant changes in the 10 micron silicate stretch feature. There is a deepening of the 10 micron silicate stretch as well as the development of a feature between about 13 and 20 microns consistent with a blend of the MgO and FeO stretching features and the O-Si-O bending mode of increasingly ordered silicate dust. Near-infrared observations show the presence of AlO and water vapor in the outflow in 2003, 2004 and 2005: the AlO has significantly decreased in spectra obtained in 2014 while the water vapor remains largely unchanged. An attempt is made to correlate these observations and understand the significance of these changes using DUSTY modeling. The observations appear consistent with the kinetically-controlled, condensation of highly under-oxidized SiO/AlO/Fe/Mg dust grains in the outflow followed by the continuous evolution of the initial condensate due to thermal annealing and oxidation of the dust via reaction with ambient O, OH and H2O in the expanding, cooling shell. Periodic monitoring of this dust shell over the mid-infrared spectral range could yield useful information on the evolution of under-oxidized silicate condensates exposed to hot water vapor in more conventional circumstellar environments.