Enregistré dans:
Détails bibliographiques
Auteurs principaux: Bickley, Thomas M., Mingare, Angus, Weaving, Tim, de la Bastida, Michael Williams, Wan, Shunzhou, Nibbi, Martina, Seitz, Philipp, Ralli, Alexis, Love, Peter J., Chung, Minh, Vera, Mario Hernández, Schulz, Laura, Coveney, Peter V.
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2505.16796
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866912744919269376
author Bickley, Thomas M.
Mingare, Angus
Weaving, Tim
de la Bastida, Michael Williams
Wan, Shunzhou
Nibbi, Martina
Seitz, Philipp
Ralli, Alexis
Love, Peter J.
Chung, Minh
Vera, Mario Hernández
Schulz, Laura
Coveney, Peter V.
author_facet Bickley, Thomas M.
Mingare, Angus
Weaving, Tim
de la Bastida, Michael Williams
Wan, Shunzhou
Nibbi, Martina
Seitz, Philipp
Ralli, Alexis
Love, Peter J.
Chung, Minh
Vera, Mario Hernández
Schulz, Laura
Coveney, Peter V.
contents The advent of hybrid computing platforms consisting of quantum processing units integrated with conventional high-performance computing brings new opportunities for algorithm design. By strategically offloading select portions of the workload to classical hardware where tractable, we may broaden the applicability of quantum computation in the near term. In this perspective, we review techniques that facilitate the study of subdomains of chemical systems with quantum computers and present a proof-of-concept demonstration of quantum-selected configuration interaction deployed within a multiscale/multiphysics simulation workflow leveraging classical molecular dynamics, projection-based embedding and qubit subspace tools. This allows the technology to be utilised for simulating systems of real scientific and industrial interest, which not only brings true quantum utility closer to realisation but is also relevant as we look forward to the fault-tolerant regime.
format Preprint
id arxiv_https___arxiv_org_abs_2505_16796
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Extending Quantum Computing through Subspace, Embedding and Classical Molecular Dynamics Techniques
Bickley, Thomas M.
Mingare, Angus
Weaving, Tim
de la Bastida, Michael Williams
Wan, Shunzhou
Nibbi, Martina
Seitz, Philipp
Ralli, Alexis
Love, Peter J.
Chung, Minh
Vera, Mario Hernández
Schulz, Laura
Coveney, Peter V.
Quantum Physics
The advent of hybrid computing platforms consisting of quantum processing units integrated with conventional high-performance computing brings new opportunities for algorithm design. By strategically offloading select portions of the workload to classical hardware where tractable, we may broaden the applicability of quantum computation in the near term. In this perspective, we review techniques that facilitate the study of subdomains of chemical systems with quantum computers and present a proof-of-concept demonstration of quantum-selected configuration interaction deployed within a multiscale/multiphysics simulation workflow leveraging classical molecular dynamics, projection-based embedding and qubit subspace tools. This allows the technology to be utilised for simulating systems of real scientific and industrial interest, which not only brings true quantum utility closer to realisation but is also relevant as we look forward to the fault-tolerant regime.
title Extending Quantum Computing through Subspace, Embedding and Classical Molecular Dynamics Techniques
topic Quantum Physics
url https://arxiv.org/abs/2505.16796