Related papers: Dynamic thermalization on noisy quantum hardware

Dynamic thermalization on noisy quantum hardware

URL: http://arxiv.org/abs/2407.04770v3
Date: Mon, 03 Feb 2025 19:00:00 GMT
Title: Dynamic thermalization on noisy quantum hardware
Authors: H. Perrin, T. Scoquart, A. I. Pavlov, N. V. Gnezdilov,
Abstract summary: Emulating thermal observables on a digital quantum computer is essential for quantum simulation of many-body physics. We show that thermal observables and fluctuations may be obtained for a small closed system without a thermal bath.
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Abstract: Emulating thermal observables on a digital quantum computer is essential for quantum simulation of many-body physics. However, thermalization typically requires a large system size due to incorporating a thermal bath, whilst limited resources of near-term digital quantum processors allow for simulating relatively small systems. We show that thermal observables and fluctuations may be obtained for a small closed system without a thermal bath. Thermal observables occur upon classically averaging quantum mechanical observables over randomized variants of their time evolution that run independently on a digital quantum processor. Using an IBM quantum computer, we experimentally find thermal occupation probabilities with finite positive and negative temperatures defined by the initial state's energy. Averaging over random evolutions facilitates error mitigation, with the noise contributing to the temperature in the simulated observables. This result fosters probing the dynamical emergence of equilibrium properties of matter at finite temperatures on noisy intermediate-scale quantum hardware.

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