Coarse-grained dynamics in quantum many-body systems using the maximum entropy principle
- URL: http://arxiv.org/abs/2407.11920v1
- Date: Tue, 16 Jul 2024 17:11:14 GMT
- Title: Coarse-grained dynamics in quantum many-body systems using the maximum entropy principle
- Authors: Adán Castillo, Carlos Pineda, Erick Sebastían Navarrete, David Davalos,
- Abstract summary: We construct an inverse map that assigns a microscopic state to a coarse-grained state based on the maximum entropy principle.
We investigate two-qubit systems, with swap and controlled-not gates, and $n$-qubit systems, configured either in an Ising spin chain or with all-to-all interactions.
We find that these dynamics exhibit atypical quantum behavior, such as non-linearity and non-Markovianity.
- Score: 0.46873264197900916
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Starting from a coarse-grained map of a quantum many-body system, we construct the inverse map that assigns a microscopic state to a coarse-grained state based on the maximum entropy principle. Assuming unitary evolution in the microscopic system, we examine the resulting dynamics in the coarse-grained system using the assignment map. We investigate both a two-qubit system, with swap and controlled-not gates, and $n$-qubit systems, configured either in an Ising spin chain or with all-to-all interactions. We demonstrate that these dynamics exhibit atypical quantum behavior, such as non-linearity and non-Markovianity. Furthermore, we find that these dynamics depend on the initial coarse-grained state and establish conditions for general microscopic dynamics under which linearity is preserved. As the effective dynamics induced by our coarse-grained description of many-body quantum systems diverge from conventional quantum behavior, we anticipate that this approach could aid in describing the quantum-to-classical transition and provide deeper insights into the effects of coarse-graining on quantum systems.
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