Related papers: Quantum homogenization in non-Markovian collisional model

Quantum homogenization in non-Markovian collisional model

URL: http://arxiv.org/abs/2201.08412v2
Date: Wed, 7 Feb 2024 19:58:27 GMT
Title: Quantum homogenization in non-Markovian collisional model
Authors: Tanmay Saha, Arpan Das and Sibasish Ghosh
Abstract summary: Collisional models are a category of microscopic framework designed to study open quantum systems. We numerically demonstrate that homogenization is achieved irrespective of the initial states of the system or bath units. A different choice of bath-bath unitary speeds up the homogenization process but loses the universality, being dependent on the initial states of the bath units.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Collisional models are a category of microscopic framework designed to study open quantum systems. The framework involves a system sequentially interacting with a bath comprised of identically prepared units. In this regard, quantum homogenization is a process where the system state approaches the identically prepared state of bath unit in the asymptotic limit. Here, we study the homogenization process for a single qubit in the non-Markovian collisional model framework generated via additional bath-bath interaction. With partial swap operation as both system-bath and bath-bath unitary, we numerically demonstrate that homogenization is achieved irrespective of the initial states of the system or bath units. This is reminiscent of the Markovian scenario, where partial swap is the unique operation for a universal quantum homogenizer. On the other hand, we observe that the rate of homogenization is slower than its Markovian counter part. Interestingly, a different choice of bath-bath unitary speeds up the homogenization process but loses the universality, being dependent on the initial states of the bath units.

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