Related papers: Long-Time Error-Mitigating Simulation of Open Quantum Systems on Near Term Quantum Computers

Long-Time Error-Mitigating Simulation of Open Quantum Systems on Near Term Quantum Computers

URL: http://arxiv.org/abs/2108.01183v2
Date: Wed, 5 Jun 2024 19:12:39 GMT
Title: Long-Time Error-Mitigating Simulation of Open Quantum Systems on Near Term Quantum Computers
Authors: Brian Rost, Lorenzo Del Re, Nathan Earnest, Alexander F. Kemper, Barbara Jones, James K. Freericks,
Abstract summary: We study an open quantum system simulation on quantum hardware, which demonstrates robustness to hardware errors even with deep circuits containing up to two thousand entangling gates. We simulate two systems of electrons coupled to an infinite thermal bath: 1) a system of dissipative free electrons in a driving electric field; and 2) the thermalization of two interacting electrons in a single orbital in a magnetic field -- the Hubbard atom. Our results demonstrate that algorithms for simulating open quantum systems are able to far outperform similarly complex non-dissipative algorithms on noisy hardware.
Score: 38.860468003121404
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We study an open quantum system simulation on quantum hardware, which demonstrates robustness to hardware errors even with deep circuits containing up to two thousand entangling gates. We simulate two systems of electrons coupled to an infinite thermal bath: 1) a system of dissipative free electrons in a driving electric field; and 2) the thermalization of two interacting electrons in a single orbital in a magnetic field -- the Hubbard atom. These problems are solved using IBM quantum computers, showing no signs of decreasing fidelity at long times. Our results demonstrate that algorithms for simulating open quantum systems are able to far outperform similarly complex non-dissipative algorithms on noisy hardware. Our two examples show promise that the driven-dissipative quantum many-body problem can eventually be solved on quantum computers.

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