Matrix Model simulations using Quantum Computing, Deep Learning, and Lattice Monte Carlo

• URL: http://arxiv.org/abs/2108.02942v1
• Date: Fri, 6 Aug 2021 05:20:02 GMT
• Title: Matrix Model simulations using Quantum Computing, Deep Learning, and Lattice Monte Carlo
• Authors: Enrico Rinaldi, Xizhi Han, Mohammad Hassan, Yuan Feng, Franco Nori, Michael McGuigan, Masanori Hanada
• Abstract summary: Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black holes. Quantum computing and deep learning offer us potentially useful approaches to study the dynamics of matrix quantum mechanics.
• Score: 1.1706540832106251
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Matrix quantum mechanics plays various important roles in theoretical physics, such as a holographic description of quantum black holes. Understanding quantum black holes and the role of entanglement in a holographic setup is of paramount importance for the development of better quantum algorithms (quantum error correction codes) and for the realization of a quantum theory of gravity. Quantum computing and deep learning offer us potentially useful approaches to study the dynamics of matrix quantum mechanics. In this paper we perform a systematic survey for quantum computing and deep learning approaches to matrix quantum mechanics, comparing them to Lattice Monte Carlo simulations. In particular, we test the performance of each method by calculating the low-energy spectrum.

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