# Momentum and energy injection by a supernova remnant into an   inhomogeneous medium

**Authors:** Julian M. Pittard

arXiv: 1907.03519 · 2019-07-17

## TL;DR

This study uses 1D hydrodynamical simulations to show how embedded clouds in an inhomogeneous medium affect supernova remnant evolution, reducing final momentum and altering energy injection.

## Contribution

It provides new insights into how mass-loading from clouds influences supernova remnant dynamics and energy transfer in inhomogeneous interstellar media.

## Key findings

- Remnants cool faster with embedded clouds.
- Final momentum can be reduced by over a factor of two.
- Later supernovae may sustain hot phases due to prior cloud destruction.

## Abstract

We investigate the effect of mass-loading from embedded clouds on the evolution of supernova remnants and on the energy and momentum that they inject into an inhomogeneous interstellar medium. We use 1D hydrodynamical calculations and assume that the clouds are numerous enough that they can be treated in the continuous limit. The destruction of embedded clouds adds mass into the remnant, increasing its density and pressure, and decreasing its temperature. The remnant cools more quickly, is less able to do PdV work on the swept-up gas, and ultimately attains a lower final momentum (by up to a factor of two or more). We thus find that the injection of momentum is more sensitive to an inhomogeneous environment than previous work has suggested, and we provide fits to our results for the situation where the cloud mass is not limited. The behaviour of the remnant is more complex in situations where the cloud mass is finite and locally runs out. In the case of multiple supernovae in a clustered environment, later supernova explosions may encounter higher densities than previous explosions due to the prior liberation of mass from engulfed clouds. If the cloud mass is finite, later explosions may be able to create a sustained hot phase when earlier explosions have not been able to.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1907.03519/full.md

## References

88 references — full list in the complete paper: https://tomesphere.com/paper/1907.03519/full.md

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Source: https://tomesphere.com/paper/1907.03519