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Main Authors: Johny, Adikiran, R, Athulkrishna, Majhi, Rudra, Sahoo, Suchismita
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2602.04800
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author Johny, Adikiran
R, Athulkrishna
Majhi, Rudra
Sahoo, Suchismita
author_facet Johny, Adikiran
R, Athulkrishna
Majhi, Rudra
Sahoo, Suchismita
contents The Deep Underground Neutrino Experiment (DUNE) offers strong sensitivity to neutrinos from a Galactic core collapse supernova, providing a powerful probe of neutrino flavor conversion and the neutrino mass ordering. In this work, we study supernova neutrino oscillations at DUNE using quantum entanglement as an organizing framework. Treating the three flavor neutrino system as an effective multipartite quantum state, we quantify flavor correlations through the entanglement of formation, concurrence, and negativity, expressed directly in terms of flavor survival and transition probabilities. Benchmark scenarios defined by representative variations of the electron neutrino survival probability are constructed for each entanglement measure. Event rates and fluences are computed for a supernova at 10 kpc, and the mass ordering sensitivity is evaluated using detector-level simulations performed with the \texttt{SNOwGLoBES} framework, employing the Garching supernova flux model and including the dominant detection channels in liquid argon: $ν_e$ and $\barν_e$ charged-current interactions on argon and elastic scattering on electrons. We analyze both individual and combined detection channels and incorporate $5\%$ normalization and energy calibration systematic uncertainties. Our results show that DUNE achieves a $5σ$ determination of the neutrino mass ordering for a supernova at distances of $\sim 20$~kpc for the $ν_e$ charged current channel and $\sim 2$~kpc for the $\barν_e$ channel, with the reach depending on the entanglement scenario considered. These results demonstrate that entanglement based observables provide a complementary and robust framework for probing supernova neutrino oscillations and the neutrino mass ordering.
format Preprint
id arxiv_https___arxiv_org_abs_2602_04800
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Exploring supernova neutrino mass ordering at DUNE via quantum entanglement
Johny, Adikiran
R, Athulkrishna
Majhi, Rudra
Sahoo, Suchismita
High Energy Physics - Phenomenology
The Deep Underground Neutrino Experiment (DUNE) offers strong sensitivity to neutrinos from a Galactic core collapse supernova, providing a powerful probe of neutrino flavor conversion and the neutrino mass ordering. In this work, we study supernova neutrino oscillations at DUNE using quantum entanglement as an organizing framework. Treating the three flavor neutrino system as an effective multipartite quantum state, we quantify flavor correlations through the entanglement of formation, concurrence, and negativity, expressed directly in terms of flavor survival and transition probabilities. Benchmark scenarios defined by representative variations of the electron neutrino survival probability are constructed for each entanglement measure. Event rates and fluences are computed for a supernova at 10 kpc, and the mass ordering sensitivity is evaluated using detector-level simulations performed with the \texttt{SNOwGLoBES} framework, employing the Garching supernova flux model and including the dominant detection channels in liquid argon: $ν_e$ and $\barν_e$ charged-current interactions on argon and elastic scattering on electrons. We analyze both individual and combined detection channels and incorporate $5\%$ normalization and energy calibration systematic uncertainties. Our results show that DUNE achieves a $5σ$ determination of the neutrino mass ordering for a supernova at distances of $\sim 20$~kpc for the $ν_e$ charged current channel and $\sim 2$~kpc for the $\barν_e$ channel, with the reach depending on the entanglement scenario considered. These results demonstrate that entanglement based observables provide a complementary and robust framework for probing supernova neutrino oscillations and the neutrino mass ordering.
title Exploring supernova neutrino mass ordering at DUNE via quantum entanglement
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2602.04800