Neutrino Decoherence in Simple Open Quantum Systems

TL;DR

This paper models neutrino decoherence in open quantum systems through various approaches, revealing universal exponential decay of coherence and connecting physical models to the Lindblad formalism.

Contribution

It introduces multiple models of neutrino decoherence in open quantum systems, linking physical mechanisms to the GKSL master equation and highlighting the universality of exponential decay.

Findings

Universal exponential decay of coherence observed across models

Connection established between physical models and Lindblad operators

Decoherence process explained within Born-Markov approximation

Abstract

Neutrinos lose coherence as they propagate, which leads to the fading away of oscillations. In this work, we model neutrino decoherence induced in open quantum systems from their interaction with the environment. We first present two different models in the quantum mechanical framework, in which the environment is modeled as forced harmonic oscillators with white noise interactions, or two-level systems with stochastic phase kicks. We then look at the decoherence process in the quantum field theoretic framework induced by elastic scatterings with environmental particles. The exponential decay is obtained as a common feature for all models, which shows the universality of the decoherence processes. We discuss connections to the GKSL master equation approach and give a clear physical meaning of the Lindblad operators. We demonstrate that the universality of exponential decay of coherence is based on the Born-Markov approximation. The models in this work are suitable to be extended to describe real physical processes that could be non-Markovian.