Two-particle Hadamard walk on dynamically percolated line and circle

• URL: http://arxiv.org/abs/2311.15579v2
• Date: Thu, 15 Feb 2024 13:45:52 GMT
• Title: Two-particle Hadamard walk on dynamically percolated line and circle
• Authors: M. Paryzkova, M. Stefanak, J. Novotny, B. Kollar and T. Kiss
• Abstract summary: Asymptotic dynamics of a Hadamard walk of two non-interacting quantum particles on a dynamically percolated finite line or a circle is investigated. We construct a basis of the attractor space of the corresponding random-unitary dynamics and prove the completeness of our solution.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Asymptotic dynamics of a Hadamard walk of two non-interacting quantum particles on a dynamically percolated finite line or a circle is investigated. We construct a basis of the attractor space of the corresponding random-unitary dynamics and prove the completeness of our solution. In comparison to the one-particle case, the structure of the attractor space is much more complex, resulting in intriguing asymptotic dynamics. General results are illustrated on two examples. First, for circles of length not divisible by 4 the boundary conditions reduces the number of attractors considerably, allowing for fully analytic solution. Second, we investigate line of length 4 and determine the asymptotic cycle of reduced coin states and position distributions, focusing on the correlations between the two particles. Our results show that a random unitary evolution, which is a combination of quantum dynamics and a classical stochasticity, leads to correlations between initially uncorrelated particles. This is not possible for purely unitary evolution of non-interacting quantum particles. The shared dynamically percolated graph can thus be considered as a weak form of interaction.

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