Simulating a low-weight encoding of the Fermi-Hubbard Model with QAOA

Joseph Barreto; Ryan Levy; Lucas Brady; Zoe Gonzalez Izquierdo; Jeffrey S Marshall; Eleanor G Rieffel; Zhihui Wang; Filip Wudarski

Simulating a low-weight encoding of the Fermi-Hubbard Model with QAOA

ORAL

Abstract

Recent work [1] has proposed a compact fermion-to-qubit mapping for the Fermi-Hubbard model (FHM), potentially lowering the overhead needed to simulate such a system on quantum hardware. In prior work [2], we numerically investigated how well a quantum annealer could prepare ground states of the FHM encoded using the resource-efficient mapping. In order to compare these results to gate-model systems, we turn to a QAOA-style approach and replace the annealing schedule with both Trotterizations thereof and also more general Hamiltonian-variational ansatze based on the terms of the mapped FH Hamiltonian. We investigate the achievable ground state fidelities of these gate sequences, consider various optimizations of the ansatze structure, and offer resource estimations of the optimized QAOA protocols for near-term hardware.

[1] Derby, Klassen, Bausch, Cubitt, Phys. Rev. B 104, 035118

[2] Levy et al. arXiv:2207.14374v1

March 10, 2023, 2:42 PM – March 10, 2023, 2:54 PM

Presenters

Joseph Barreto

USC, QuAIL, USRA, NASA

Authors

Joseph Barreto

USC, QuAIL, USRA, NASA
Ryan Levy

Center for Computational Quantum Physics, Flatiron Institute
Lucas Brady

QuAIL, USRA, NASA, National Institute of Standards and Tech
Zoe Gonzalez Izquierdo

QuAIL, USRA, NASA, USRA - Univ Space Rsch Assoc
Jeffrey S Marshall

QuAIL, USRA, NASA
Eleanor G Rieffel

QuAIL, NASA, NASA Ames Research Center
Zhihui Wang

QuAIL, USRA, NASA, USRA - Univ Space Rsch Assoc
Filip Wudarski

QuAIL, USRA, NASA