Quantum correlations of a two-qubit system and the Aubry-Andr\'{e} chain in bosonic environments

TL;DR

This paper investigates how non-Markovian environments influence quantum correlations in two-qubit systems and Aubry-Andre9 chains, revealing mechanisms for protecting and understanding quantum entanglement dynamics in disordered and bosonic environments.

Contribution

It introduces a tensor network approach to analyze quantum correlations in bosonic reservoirs and explores phase-dependent entanglement behavior in Aubry-Andre9 chains with environmental coupling.

Findings

Non-Markovian effects extend quantum correlation survival time.

Entanglement rebirth occurs in non-Markovian dynamics.

Disordered environments can serve as buffers to protect quantum correlations.

Abstract

In this research, we analyze two models using the tensor network algorithm. The quantum correlations of a two-qubit system are first studied in different bosonic reservoirs. Both equilibrium and nonequilibrium scenarios are discussed. Non-Markovian effects can improve the survival time of the quantum correlations significantly and weaken the decoherence effect. Non-Markovian dynamics with existing memory can lead to entanglement rebirth in specific scenarios instead of the eventual entanglement decay or death seen in memoryless Markovian cases. The system reaches a steady state quickest in sub-Ohmic reservoirs and shows the most apparent non-Markovian behavior in super-Ohmic reservoirs. We not only study the impact of the environment on quantum correlations but also how to protect quantum correlations. Starting from a state in which the two ends are maximally entangled, a one-dimensional AA chain model is also studied. We identify distinct phases by monitoring the imbalance dynamics. When the chain is closed, the imbalance dynamics behave differently in various phases, and so does the entanglement evolution between the chain's ends. When the first site couples to a bath, we found the imbalance dynamics can still be an effective indicator to differentiate various phases in an early evolution stage since the imbalance dynamics is only remarkably affected at relatively high temperatures. The distribution of the eigenenergy of the system can account for it. The entanglement of the chain ends decays rapidly in all phases due to one of the ends being coupled to the bath directly. However, the entanglement of the chain ends will persist for a perceptible amount of time in the localization phase if the bath is coupled to the middle site of the chain. Our research shows that one can utilize the disordered environment as a buffer to protect quantum correlations.