Evolution of the stellar-merger red nova V1309 Scorpii: SED analysis

TL;DR

This study analyzes the spectral energy distribution of red nova V1309 Sco before and after its 2008 merger, revealing dust formation, mass-loss, and evolution consistent with stellar merger models.

Contribution

It provides detailed SED analysis over time, demonstrating dust formation and mass-loss in V1309 Sco, confirming the stellar merger origin of red novae.

Findings

Presence of freshly formed dust with high temperature (~900-1000 K) before eruption.

Post-outburst dust envelope indicates matter lost during the 2008 event.

Detection of cold (~30 K) dust at large distances from the object.

Abstract

One very important object for understanding the nature of red novae is V1309 Sco. Its pre-outburst observations showed that, before its red-nova eruption in 2008, it was a contact binary quickly evolving to the merger of the components. It thus provided us with a direct evidence that the red novae result from stellar mergers. We analyse the spectral energy distribution (SED) of the object and its evolution with time. From various optical and infrared surveys and observing programmes carried out with OGLE, HST, VVV, Gemini South, WISE, Spitzer, and Herschel we constructed observed SED in 2010 and 2012. Some limited data are also available for the red-nova progenitor in 2007. We analyse the data with our model of a dusty envelope surrounding a central star. Dust was present in the pre-outburst state of V1309 Sco. Its high temperature (900-1000 K) suggests that this was a freshly formed dust in a presumable mass-loss from the spiralling-in binary. Shortly after its 2008 eruption, V1309~Sco became almost completely embedded in dust. The parameters (temperature, dimensions) of the dusty envelope in 2010 and 2012 evidence that we then observed matter lost by the object during the 2008 outburst. Its mass is at least $10^{-3}\,M_\odot$. The object remains quite luminous, although since its maximum brightness in September 2008, it has faded in luminosity by a factor of ~50 (in 2012). Far infrared data from Herschel reveal presence of a cold (~30 K) dust at a distance of a few thousand AU from the object. This conclusion could be verified by submillimeter interferometric observations.