Related papers: Quantum-embeddable stochastic matrices

Quantum-embeddable stochastic matrices

URL: http://arxiv.org/abs/2305.17163v2
Date: Tue, 2 Jul 2024 08:39:24 GMT
Title: Quantum-embeddable stochastic matrices
Authors: Fereshte Shahbeigi, Christopher T. Chubb, Ryszard Kukulski, Łukasz Pawela, Kamil Korzekwa,
Abstract summary: We investigate the quantum version of the classical embeddability problem. We show that a larger set of transition matrices can be explained by memoryless models. We also identify a non-zero measure set of random processes that cannot be explained by either classical or quantum memoryless dynamics.
Score: 2.038893829552158
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: The classical embeddability problem asks whether a given stochastic matrix $T$, describing transition probabilities of a $d$-level system, can arise from the underlying homogeneous continuous-time Markov process. Here, we investigate the quantum version of this problem, asking of the existence of a Markovian quantum channel generating state transitions described by a given $T$. More precisely, we aim at characterising the set of quantum-embeddable stochastic matrices that arise from memoryless continuous-time quantum evolution. To this end, we derive both upper and lower bounds on that set, providing new families of stochastic matrices that are quantum-embeddable but not classically-embeddable, as well as families of stochastic matrices that are not quantum-embeddable. As a result, we demonstrate that a larger set of transition matrices can be explained by memoryless models if the dynamics is allowed to be quantum, but we also identify a non-zero measure set of random processes that cannot be explained by either classical or quantum memoryless dynamics. Finally, we fully characterise extreme stochastic matrices (with entries given only by zeros and ones) that are quantum-embeddable.

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