Abstract
We consider a microscopic collision model, i.e., a quantum system interacts with a hierarchical environment consisting of an auxiliary system and a reservoir. We show how the non-Markovian character of the system is influenced by the coupling strength of system-auxiliary system and auxiliary system-reservoir, coherence of environment and initial system-environment correlations. And we study the non-Markovianity induced by coherence of environment from the perspective of energy, further the relationship between information backflow and energy flux is obtained. Then we study the effect of non-Markovianity on thermodynamic properties. By studying the entropy change of system especially that from heat exchanges with the environment, we reveal the essence of entropy change between positive and negative values during non-Markovian evolution is due to the contribution of heat flux induced by coherence. And compared with the case of Markovian dynamics, we observe that the entropy production decreases in some specific time intervals under non-Markovian dynamics induced by the coupling strength. And this is different to the case of non-Markovianity caused by initial system-environment correlation, that we show the possibility of positive entropy production during the whole dynamics.
Highlights
The study of open quantum systems is of great importance in quantum information and computation recently
4 Conclusion In this paper, we have investigated the non-Markovian character of the system and its effect on thermodynamic properties by means of a collision model, that a system is coupled to a structured environment consisting of a auxiliary system and a reservoir
We have studied how the system-auxiliary system and auxiliary system-reservoir coupling strength, coherence of environment and initial system-environment correlation affect the nonMarkovian character of the system
Summary
The study of open quantum systems is of great importance in quantum information and computation recently. The Markovian approximation is important to describe the dynamics of open quantum system either in terms of maps and Kraus operators or in terms of master equations [1]. With the help of these measures, one can claim that an evolution is non-Markovian if a nonzero degree of NM is detected. The transition from Markovian to non-Markovian dynamics has been theoretically and experimentally implemented based on these measures [25,26,27,28,29,30,31]. An interesting question concerns how the independent role of these factors to influence the system dynamics, systemenvironment coupling, initial system-environment correlations and the intraenvironment coherence
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