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Main Authors: Bora, Himanshu, Dutta, Debajyoti, Medhi, Abinash
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.06953
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author Bora, Himanshu
Dutta, Debajyoti
Medhi, Abinash
author_facet Bora, Himanshu
Dutta, Debajyoti
Medhi, Abinash
contents We examine the sensitivity of the ESSnuSB and DUNE long-baseline neutrino experiments to isotropic, CPT-violating Lorentz Invariance Violation (LIV). Using detailed simulations for the 360 km and 540 km ESSnuSB baselines and the 1300 km DUNE setup, we assess how LIV parameters influence oscillation probabilities, event spectra, and degeneracies among oscillation parameters. We find that LIV-induced modifications can closely mimic variations in $θ_{23}$ and $δ_{\rm CP}$, potentially leading to incorrect determination of the atmospheric mixing angle octant and the leptonic CP phase if LIV effects are not accounted for. Although combining the two ESSnuSB baselines improves overall sensitivity, it does not fully remove these degeneracies. In contrast, a joint ESSnuSB+DUNE analysis benefiting from the synergy between second-maximum sensitivity at ESSnuSB and first-maximum, matter-enhanced sensitivity at DUNE can successfully resolve all these degeneracies and can yield significantly stronger constraints on all the LIV parameters. The results presented here highlights the essential role of multi-baseline, multi-energy experimental strategies to probe Planck-suppressed Lorentz-violating new physics.
format Preprint
id arxiv_https___arxiv_org_abs_2512_06953
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Constraining and Resolving Lorentz-Violating New Physics at ESSnuSB Using Complementarity with DUNE
Bora, Himanshu
Dutta, Debajyoti
Medhi, Abinash
High Energy Physics - Phenomenology
We examine the sensitivity of the ESSnuSB and DUNE long-baseline neutrino experiments to isotropic, CPT-violating Lorentz Invariance Violation (LIV). Using detailed simulations for the 360 km and 540 km ESSnuSB baselines and the 1300 km DUNE setup, we assess how LIV parameters influence oscillation probabilities, event spectra, and degeneracies among oscillation parameters. We find that LIV-induced modifications can closely mimic variations in $θ_{23}$ and $δ_{\rm CP}$, potentially leading to incorrect determination of the atmospheric mixing angle octant and the leptonic CP phase if LIV effects are not accounted for. Although combining the two ESSnuSB baselines improves overall sensitivity, it does not fully remove these degeneracies. In contrast, a joint ESSnuSB+DUNE analysis benefiting from the synergy between second-maximum sensitivity at ESSnuSB and first-maximum, matter-enhanced sensitivity at DUNE can successfully resolve all these degeneracies and can yield significantly stronger constraints on all the LIV parameters. The results presented here highlights the essential role of multi-baseline, multi-energy experimental strategies to probe Planck-suppressed Lorentz-violating new physics.
title Constraining and Resolving Lorentz-Violating New Physics at ESSnuSB Using Complementarity with DUNE
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2512.06953