English

Double-bracket quantum algorithms for high-fidelity ground state preparation

Quantum Physics 2025-11-07 v2

Abstract

Ground state preparation is a central application for quantum computers but remains challenging in practice. In this work, we quantitatively investigate the performance and gate counts of double-bracket quantum algorithms (DBQAs) for ground state preparation. We propose a practical strategy in which DBQAs refine initial state preparation circuits, and we compile them for Heisenberg chains using controlled-Z and single-qubit gates. Warm-started DBQAs consistently improve both the energy and ground-state fidelity relative to the initial states provided by variational ans\"atze, indicating that DBQAs offer an effective unitary synthesis method. To demonstrate compatibility with near-term hardware, we executed a proof-of-concept example on IBM devices. With error mitigation, we observed a statistically significant improvement over the corresponding warm-start circuit. Furthermore, numerical emulations for the same system size indicate that executing DBQAs on Quantinuum's hardware could achieve similar cost-function gains without requiring error mitigation. These findings suggest that DBQAs are a promising approach for enhancing ground-state approximations on near-term quantum devices.

Keywords

Cite

@article{arxiv.2408.03987,
  title  = {Double-bracket quantum algorithms for high-fidelity ground state preparation},
  author = {Matteo Robbiati and Edoardo Pedicillo and Andrea Pasquale and Xiaoyue Li and Oriel Kiss and Andrew Wright and Renato M. S. Farias and Khanh Uyen Giang and Jeongrak Son and Johannes Knörzer and Siong Thye Goh and Jun Yong Khoo and Nelly H. Y. Ng and Zoë Holmes and Stefano Carrazza and Marek Gluza},
  journal= {arXiv preprint arXiv:2408.03987},
  year   = {2025}
}

Comments

11 pages + appendix, 5 figures, code available at: https://github.com/qiboteam/boostvqe

R2 v1 2026-06-28T18:06:53.659Z