# Interaction of hemispherical blast waves with inhomogeneous spheres:   Probing the collision of a supernova ejecta with a nearby companion star in   the laboratory

**Authors:** Domingo Garc\'ia-Senz, Pedro Velarde, Francisco Suzuki-Vidal, Chantal, Stehl\'e, Manuel Cotelo, David Portillo, Tomasz Plewa, Arthur Pak

arXiv: 1812.06285 · 2018-12-18

## TL;DR

This paper proposes a novel laboratory experiment setup to simulate supernova ejecta interacting with a companion star, incorporating shock curvature and density stratification to better mimic astrophysical conditions.

## Contribution

The work introduces a new experimental platform that models supernova ejecta interactions with inhomogeneous, curved targets, advancing laboratory astrophysics capabilities.

## Key findings

- Qualitative agreement with astrophysical models
- Design effectively captures ejecta-companion interaction features
- Potential to study diverse supernova scenarios

## Abstract

Past high-energy density laboratory experiments provided insights into the physics of supernovae, supernova remnants, and the destruction of interstellar clouds. In a typical experimental setting, a laser-driven planar blast wave interacts with a compositionally-homogeneous spherical or cylindrical target. In this work we propose a new laboratory platform that accounts for curvature of the impacting shock and density stratification of the target. Both characteristics reflect the conditions expected to exist shortly after a supernova explosion in a close binary system. We provide details of a proposed experimental design (laser drive, target configuration, diagnostic system), optimized to capture the key properties of recent ejecta-companion interaction models. Good qualitative agreement found between our experimental models and their astrophysical counterparts highlights strong potential of the proposed design to probe details of the ejecta-companion interaction for broad classes of objects by means of high energy density laboratory experiments.

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Source: https://tomesphere.com/paper/1812.06285