The four-momentum conservation and equal velocity assumption in neutrino oscillations

TL;DR

This paper introduces a new four-momentum conservation framework and an equal velocity assumption for neutrino oscillations, leading to distinctive predictions for energy-momentum relations and phase differences that can be experimentally tested.

Contribution

It derives a novel form of four-momentum conservation and explores the implications of the equal velocity assumption on neutrino oscillation phase differences and energy-momentum relations.

Findings

The EMSD is constant under the equal velocity assumption.

EMS D varies with energy or momentum under equal energy or momentum assumptions.

The phase difference depends linearly on L/E and mass difference under the equal velocity assumption.

Abstract

The neutrino masses and oscillation are closely related to how neutrino propagates. In this paper, we first derive a new form of four-momentum conservation that connects the four-momentum $(E_{\alpha},~p_{\alpha})$ of the neutrino flavor eigenstate and the four momenta $(E_i,~p_i)$ of its mass eigen-components. Then we use the assumption that the mass eigen-components travel at equal velocity to derive the energy-momentum square difference (EMSD) $E_{\alpha}^2-p_{\alpha}^2$ for the flavor eigenstate. It is shown that for the equal velocity assumption, $E_{\alpha}^2-p_{\alpha}^2$ will be a fixed constant in events with different $E_{\alpha}$ and/or $p_{\alpha}$. In contrast, for the equal energy or equal momentum assumption, $E_{\alpha}^2-p_{\alpha}^2$ will vary with $E_{\alpha}$ or $p_{\alpha}$ respectively. These EMSD can be checked by ongoing and future neutrino experiments. The phase difference between two neutrino mass eigen-components $|\nu_i\rangle$ and $|\nu_j\rangle$ is then derived for the equal velocity assumption. For relativistic neutrinos, it is shown that the phase difference depends linearly on the distance energy ratio $L/E$, the mass difference $m_i-m_j$ and an effective mass, in contrary to the linear dependance on $L/E$ and $m_i^2-m_j^2$ as the phase difference for equal energy or equal momentum assumption dose. The new phase difference implies different bounds on the neutrino masses or mass difference.