# Neutrino emissions in all flavors up to the pre-bounce of massive stars   and the possibility of their detections

**Authors:** Chinami Kato, Hiroki Nagakura, Shun Furusawa, Koh Takahashi, Hideyuki, Umeda, Takashi Yoshida, Koji Ishidoshiro, Shoichi Yamada

arXiv: 1704.05480 · 2017-10-18

## TL;DR

This study models all-flavor neutrino emissions from massive star pre-bounce phases, estimating detection prospects at terrestrial detectors like DUNE and JUNO, and highlighting how neutrino signals can distinguish supernova progenitor types.

## Contribution

It extends previous work by including all neutrino flavors and analyzing detection possibilities for various supernova progenitors with upcoming detectors.

## Key findings

- Electron neutrino luminosities reach ~10^{57} s^{-1}
- Detection of electron neutrinos at DUNE is feasible for certain supernova types
- Electron antineutrinos from ECSN are generally undetectable at current detectors.

## Abstract

This paper is a sequel to our previous one (Kato et al.2015), which calculated the luminosities and spectra of electron-type anti-neutrinos ($\bar{\nu}_e$'s) from the progenitors of core-collapse supernovae. Expecting that a capability to detect electron-type neutrinos ($\nu_e$'s) will increase dramatically with the emergence of liquid-argon detectors such as DUNE, we broaden the scope in this study to include all-flavors of neutrinos emitted from the pre-bounce phase. We pick up three progenitor models of an electron capture supernova (ECSN) and iron-core collapse supernovae (FeCCSNe). We find that the number luminosities reach $\sim10^{57} \mathrm{s^{-1}}$ and $\sim10^{53} \mathrm{s^{-1}}$ at maximum for $\nu_e$ and $\bar{\nu}_e$, respectively. We also estimate the numbers of detection events at terrestrial neutrino detectors including DUNE, taking flavor oscillations into account and assuming the distance to the progenitors to be 200 pc. It is demonstrated that $\bar{\nu}_e$'s from the ECSN-progenitor will be undetected at almost all detectors, whereas we will be able to observe $\gtrsim$15900 $\nu_e$'s at DUNE for the inverted mass hierarchy. From the FeCCSN-progenitors, the number of $\bar{\nu}_e$ events will be largest for JUNO, 200-900 $\bar{\nu}_e$'s, depending on the mass hierarchy whereas the number of $\nu_e$ events at DUNE is $\gtrsim$2100 for the inverted mass hierarchy. These results imply that the detection of $\bar{\nu}_e$'s is useful to distinguish FeCCSN- from ECSN-progenitors, while $\nu_e$'s will provide us with detailed information on the collapse phase regardless of the type and mass of progenitor.

## Full text

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Source: https://tomesphere.com/paper/1704.05480