Quantum-enhanced Markov chain Monte Carlo for systems larger than a quantum computer

Quantum-enhanced Markov chain Monte Carlo for systems larger than a quantum computer

Quantum computers theoretically promise computational advantages in many tasks, but it is much less clear how such advantages can be maintained when using existing and near-term hardware that has limitations in the number and quality of its qubits. Layden et al. [Nature (London) 619, 282 (2023)0028-...

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Bibliographic Details
Main Authors: Stuart Ferguson, Petros Wallden
Format: Article
Language:English
Published: American Physical Society 2025-03-01
Series:Physical Review Research
Online Access:http://doi.org/10.1103/PhysRevResearch.7.013231
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Summary:Quantum computers theoretically promise computational advantages in many tasks, but it is much less clear how such advantages can be maintained when using existing and near-term hardware that has limitations in the number and quality of its qubits. Layden et al. [Nature (London) 619, 282 (2023)0028-083610.1038/s41586-023-06095-4] proposed a promising application by introducing a quantum-enhanced Markov chain Monte Carlo (QeMCMC) approach to reduce the thermalization time required when sampling from hard probability distributions. In QeMCMC, the size of the required quantum computer scales linearly with the problem, placing limitations on the sizes of systems that can be considered. In this paper we introduce a framework to coarse grain the algorithm in such a way that the quantum computation can be performed using considerably smaller quantum computers and we term the method the coarse grained quantum-enhanced Markov chain Monte Carlo (CGQeMCMC). Example strategies within this framework are put to the test, with the quantum speedup persisting while using only sqrt[n] simulated qubits where n is the number of qubits required in the original QeMCMC—a quadratic reduction in resources. The coarse graining framework has the potential to be practically applicable in the near term as it requires very few qubits to approach classically intractable problem instances; in this case, only six simulated qubits suffice to gain an advantage compared with standard classical approaches when investigating the magnetization of a 36-spin system. Our method can be easily combined with other classical and quantum techniques and is adaptable to various quantum hardware specifications—in particular those with limited connectivity.
ISSN:2643-1564

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