Dynamics of entanglement in systems of identical fermions undergoing decoherence

TL;DR

This paper investigates how entanglement evolves in systems of identical fermions under decoherence, introducing new measures and analyzing dynamics to better understand and control quantum information loss.

Contribution

It introduces new entanglement measures and analyzes the dynamics of entanglement in identical-fermion systems under decoherence, providing novel insights into multipartite entanglement.

Findings

Entanglement dynamics depend on the type of quantum channel.

New entanglement measures effectively quantify fermionic entanglement.

Analysis reveals emergence of multipartite genuine entanglement.

Abstract

Information that is stored in quantum-mechanical systems can be easily lost because of the interaction with the environment in a process known as decoherence. Possible physical implementations of many processes in quantum information theory involve systems of identical particles, whence comprehension of the dynamics of entanglement induced by decoherence processes in identical-particle open systems becomes relevant. Here we study the effects, and concomitant entanglement evolution, arising from the interaction between a system of two identical fermions and the environment, for two paradigmatic quantum channels. New entanglement measures are introduced to quantify the entanglement between the different parties, and a study of the dynamics of entanglement for some particular examples is carried out. Our analysis, which includes also the evolution of an entanglement indicator based on an entropic criteria, offers new insights into the dynamics of entanglement in open systems of identical particles, involving the emergence of multipartite genuine entanglement. The results improve our understanding of the phenomenon of decoherence and will provide new strategies to control it.