# Common envelope light-curves - I. grid-code module calibration

**Authors:** Pablo Galaviz, Orsola De Marco, Jean-Claude Passy, Jan E. Staff and, Roberto Iaconi

arXiv: 1702.07872 · 2017-04-19

## TL;DR

This paper introduces a method for post-processing grid-based simulations of common envelope interactions to generate light curves, aiding comparison with observations and advancing understanding of these complex stellar events.

## Contribution

It presents a zeroth order approach for calculating luminosity from 3D hydrodynamic simulations of common envelopes, addressing current simulation limitations.

## Key findings

- Implemented a light-curve calculation method for common envelope simulations.
- Identified key obstacles in producing realistic light curves.
- Compared simulation results with recent transient observations.

## Abstract

The common envelope binary interaction occurs when a star transfers mass onto a companion that cannot fully accrete it. The interaction can lead to a merger of the two objects or to a close binary. The common envelope interaction is the gateway of all evolved compact binaries, all stellar mergers and likely many of the stellar transients witnessed to date. Common envelope simulations are needed to understand this interaction and to interpret stars and binaries thought to be the byproduct of this stage. At this time, simulations are unable to reproduce the few observational data available and several ideas have been put forward to address their shortcomings. The need for more definitive simulation validation is pressing, and is already being fulfilled by observations from time-domain surveys. In this article, we present an initial method and its implementation for post-processing grid-based common envelope simulations to produce the light-curve so as to compare simulations with upcoming observations. Here we implemented a zeroth order method to calculate the light emitted from common envelope hydrodynamic simulations carried out with the 3D hydrodynamic code Enzo used in uni-grid mode. The code implements an approach for the computation of luminosity in both optically thick and optically thin regimes and is tested using the first 135 days of the common envelope simulation of Passy et al. (2012), where a 0.8 solar masses red giant branch star interacts with a 0.6 solar masses companion. This code is used to highlight two large obstacles that need to be overcome before realistic light curves can be calculated. We explain the nature of these problems and the attempted solutions and approximations in full detail to enable the next step to be identified and implemented. We also discuss our simulation in relation to recent data of transients identified as common envelope interactions.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1702.07872/full.md

## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1702.07872/full.md

## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1702.07872/full.md

---
Source: https://tomesphere.com/paper/1702.07872