# Gravitational Wave Emission from 3D Explosion Models of Core-Collapse   Supernovae with Low and Normal Explosion Energies

**Authors:** Jade Powell, Bernhard M\"uller

arXiv: 1812.05738 · 2019-05-22

## TL;DR

This study models gravitational wave signals from 3D core-collapse supernovae with varying explosion energies, providing insights into their detectability with current and future gravitational wave detectors.

## Contribution

It presents extended 3D supernova waveforms reaching into the explosion phase for the first time, analyzing their gravitational wave emission and detection prospects.

## Key findings

- Surface g-mode oscillations in proto-neutron stars produce detectable gravitational waves.
- Peak amplitudes are higher than in previous early-phase models.
- Detection distances vary significantly between models and detectors.

## Abstract

Understanding gravitational wave emission from core-collapse supernovae will be essential for their detection with current and future gravitational wave detectors. This requires a sample of waveforms from modern 3D supernova simulations reaching well into the explosion phase, where gravitational wave emission is expected to peak. However, recent waveforms from 3D simulations with multi-group neutrino transport do not reach far into the explosion phase, and some are still obtained from non-exploding models. We therefore calculate waveforms up to 0.9\,s after bounce using the neutrino hydrodynamics code \textsc{CoCoNuT-FMT}. We consider two models with low and normal explosion energy, namely explosions of an ultra-stripped progenitor with an initial helium star mass of $3.5\,M_{\odot}$, and of an $18\,M_{\odot}$ single star. Both models show gravitational wave emission from the excitation of surface g-modes in the proto-neutron star with frequencies between $\mathord{\sim}800\,\mathrm{Hz}$ and 1000\,Hz at peak emission. The peak amplitudes are about $6\, \mathrm{cm}$ and $10\, \mathrm{cm}$, respectively, which is somewhat higher than in most recent 3D models of the pre-explosion or early explosion phase. Using a Bayesian analysis, we determine the maximum detection distances for our models in simulated Advanced LIGO, Advanced Virgo, and Einstein Telescope design sensitivity noise. The more energetic $18 M_\odot$ explosion will be detectable to about $17.5 \,\mathrm{kpc}$ by the LIGO/Virgo network and to about $180\, \mathrm{kpc}$ with the Einstein Telescope.

## Full text

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## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/1812.05738/full.md

## References

86 references — full list in the complete paper: https://tomesphere.com/paper/1812.05738/full.md

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Source: https://tomesphere.com/paper/1812.05738