English

Computation of Green's function by local variational quantum compilation

Quantum Physics 2023-08-03 v1

Abstract

Computation of the Green's function is crucial to study the properties of quantum many-body systems such as strongly correlated systems. Although the high-precision calculation of the Green's function is a notoriously challenging task on classical computers, the development of quantum computers may enable us to compute the Green's function with high accuracy even for classically-intractable large-scale systems. Here, we propose an efficient method to compute the real-time Green's function based on the local variational quantum compilation (LVQC) algorithm, which simulates the time evolution of a large-scale quantum system using a low-depth quantum circuit constructed through optimization on a smaller-size subsystem. Our method requires shallow quantum circuits to calculate the Green's function and can be utilized on both near-term noisy intermediate-scale and long-term fault-tolerant quantum computers depending on the computational resources we have. We perform a numerical simulation of the Green's function for the one- and two-dimensional Fermi-Hubbard model up to 4×44\times4 sites lattice (32 qubits) and demonstrate the validity of our protocol compared to a standard method based on the Trotter decomposition. We finally present a detailed estimation of the gate count for the large-scale Fermi-Hubbard model, which also illustrates the advantage of our method over the Trotter decomposition.

Keywords

Cite

@article{arxiv.2303.15667,
  title  = {Computation of Green's function by local variational quantum compilation},
  author = {Shota Kanasugi and Shoichiro Tsutsui and Yuya O. Nakagawa and Kazunori Maruyama and Hirotaka Oshima and Shintaro Sato},
  journal= {arXiv preprint arXiv:2303.15667},
  year   = {2023}
}

Comments

22 pages, 13 figures

R2 v1 2026-06-28T09:37:01.226Z