Related papers: Statistical Mechanics of Stochastic Quantum Control: $d$-adic Rényi Circuits

Statistical Mechanics of Stochastic Quantum Control: $d$-adic Rényi Circuits

URL: http://arxiv.org/abs/2404.16087v1
Date: Wed, 24 Apr 2024 18:00:00 GMT
Title: Statistical Mechanics of Stochastic Quantum Control: $d$-adic Rényi Circuits
Authors: Andrew A. Allocca, Conner LeMaire, Thomas Iadecola, Justin H. Wilson,
Abstract summary: We study the dynamics of quantum information in many-body systems with large onsite dimension quantities. We reveal a connection between three separate models: the classically chaotic $d$-adic R'nyi map with universality control, a quantum analog of this map for qudits, and a Potts model on a random graph.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The dynamics of quantum information in many-body systems with large onsite Hilbert space dimension admits an enlightening description in terms of effective statistical mechanics models. Motivated by this fact, we reveal a connection between three separate models: the classically chaotic $d$-adic R\'{e}nyi map with stochastic control, a quantum analog of this map for qudits, and a Potts model on a random graph. The classical model and its quantum analog share a transition between chaotic and controlled phases, driven by a randomly applied control map that attempts to order the system. In the quantum model, the control map necessitates measurements that concurrently drive a phase transition in the entanglement content of the late-time steady state. To explore the interplay of the control and entanglement transitions, we derive an effective Potts model from the quantum model and use it to probe information-theoretic quantities that witness both transitions. The entanglement transition is found to be in the bond-percolation universality class, consistent with other measurement-induced phase transitions, while the control transition is governed by a classical random walk. These two phase transitions merge as a function of model parameters, consistent with behavior observed in previous small-size numerical studies of the quantum model.

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