Enhancement of quantum correlations and geometric phase for a driven bipartite quantum system in a structured environment

TL;DR

This paper investigates how driving and environmental interactions affect quantum correlations and geometric phase in a bipartite system, providing insights for optimizing quantum state preservation in practical settings.

Contribution

It analyzes the impact of driving and transverse coupling on quantum correlations and geometric phase in a structured environment, offering new understanding for quantum system control.

Findings

Driving can enhance or degrade entanglement depending on resonance conditions.

Transverse coupling influences the evolution of quantum correlations.

Driving affects the geometric phase acquired by the entangled state.

Abstract

We study the role of driving in an initial maximally entangled state evolving under the presence of a structured environment in a weak and strong regime. We focus on the enhancement and degradation of maximal Concurrence when the system is driven on and out of resonance for a general evolution, as well as the effect of adding a transverse coupling among the particles of the model. We further investigate the role of driving in the acquisition of a geometric phase for the maximally entangled state. As the model studied herein can be used to model experimental situations such as hybrid quantum classical systems feasible with current technologies, this knowledge can aid the search for physical setups that best retain quantum properties under dissipative dynamics.