# Neutrino oscillations in a trapping potential

**Authors:** Lucas Johns

arXiv: 1906.01673 · 2019-10-08

## TL;DR

This paper explores how neutrino oscillations are affected when neutrinos are confined in a potential well, revealing corrections to oscillation frequencies due to discrete energy levels and mass-dependent zero-point energies.

## Contribution

It introduces a novel analysis of neutrino oscillations within a trapping potential, highlighting frequency shifts caused by discrete energy levels and mass-dependent zero-point energies.

## Key findings

- Frequency shifts due to discrete energy levels.
- Oscillation corrections from mass-dependent zero-point energies.
- Insights into flavor oscillations in confined systems.

## Abstract

A number of derivations of the standard neutrino oscillation formula are known, each one providing its own unique insights. Common to all treatments is the assumption that neutrinos propagate freely between source and detector, as indeed they do in all experiments thus far conducted. Here we consider how neutrinos oscillate when, contrary to the usual set-up, they are bound in a potential well. The focus in particular is on nonrelativistic neutrinos with quasi-degenerate masses, for which oscillations in free space are described by the same formula, to lowest order, as relativistic neutrinos. Trapping these particles engenders corrections to their oscillation frequencies because the interference terms are between discrete energy levels rather than continuous spectra. Especially novel is the frequency shift that occurs due to the dependence of the energy levels on the mass of the neutrino: this part of the correction is nonvanishing even in the extremely nonrelativistic limit, reflecting the fact that the neutrino mass states have different zero-point energies in the well. Building an apparatus that can trap neutrinos is a futuristic prospect to say the least, but these calculations nonetheless shine a light on certain basic aspects of the flavor-oscillation phenomenon.

## Full text

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## References

30 references — full list in the complete paper: https://tomesphere.com/paper/1906.01673/full.md

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Source: https://tomesphere.com/paper/1906.01673