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Main Authors: Buchs, Gilles, Beck, Thomas, Bennink, Ryan, Claudino, Daniel, Delgado, Andrea, Fadel, Nur Aiman, Groszkowski, Peter, Hamilton, Kathleen, Humble, Travis, Kumar, Neeraj, Li, Ang, Lotshaw, Phillip, Mukkula, Olli, Takano, Ryousei, Saxena, Amit, Suh, In-Saeng, Tsuji, Miwako, Van Beeumen, Roel, Varetto, Ugo, Wang, Yan, Yamazaki, Kazuya, Johansson, Mikael P.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.11765
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author Buchs, Gilles
Beck, Thomas
Bennink, Ryan
Claudino, Daniel
Delgado, Andrea
Fadel, Nur Aiman
Groszkowski, Peter
Hamilton, Kathleen
Humble, Travis
Kumar, Neeraj
Li, Ang
Lotshaw, Phillip
Mukkula, Olli
Takano, Ryousei
Saxena, Amit
Suh, In-Saeng
Tsuji, Miwako
Van Beeumen, Roel
Varetto, Ugo
Wang, Yan
Yamazaki, Kazuya
Johansson, Mikael P.
author_facet Buchs, Gilles
Beck, Thomas
Bennink, Ryan
Claudino, Daniel
Delgado, Andrea
Fadel, Nur Aiman
Groszkowski, Peter
Hamilton, Kathleen
Humble, Travis
Kumar, Neeraj
Li, Ang
Lotshaw, Phillip
Mukkula, Olli
Takano, Ryousei
Saxena, Amit
Suh, In-Saeng
Tsuji, Miwako
Van Beeumen, Roel
Varetto, Ugo
Wang, Yan
Yamazaki, Kazuya
Johansson, Mikael P.
contents Quantum computing (QC) has gained significant attention over the past two decades due to its potential for speeding up classically demanding tasks. This transition from an academic focus to a thriving commercial sector is reflected in substantial global investments. While advancements in qubit counts and functionalities continues at a rapid pace, current quantum systems still lack the scalability for practical applications, facing challenges such as too high error rates and limited coherence times. This perspective paper examines the relationship between QC and high-performance computing (HPC), highlighting their complementary roles in enhancing computational efficiency. It is widely acknowledged that even fully error-corrected QCs will not be suited for all computational task. Rather, future compute infrastructures are anticipated to employ quantum acceleration within hybrid systems that integrate HPC and QC. While QCs can enhance classical computing, traditional HPC remains essential for maximizing quantum acceleration. This integration is a priority for supercomputing centers and companies, sparking innovation to address the challenges of merging these technologies. The Accelerated Data Analytics and Computing Institute (ADAC) is comprised of globally leading HPC centers. ADAC has established a Quantum Computing Working Group to promote and catalyze collaboration among its members. This paper synthesizes insights from the QC Working Group, supplemented by findings from a member survey detailing ongoing projects and strategic directions. By outlining the current landscape and challenges of QC integration into HPC ecosystems, this work aims to provide HPC specialists with a deeper understanding of QC and its future implications for computationally intensive endeavors.
format Preprint
id arxiv_https___arxiv_org_abs_2508_11765
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Role of Quantum Computing in Advancing Scientific High-Performance Computing: A perspective from the ADAC Institute
Buchs, Gilles
Beck, Thomas
Bennink, Ryan
Claudino, Daniel
Delgado, Andrea
Fadel, Nur Aiman
Groszkowski, Peter
Hamilton, Kathleen
Humble, Travis
Kumar, Neeraj
Li, Ang
Lotshaw, Phillip
Mukkula, Olli
Takano, Ryousei
Saxena, Amit
Suh, In-Saeng
Tsuji, Miwako
Van Beeumen, Roel
Varetto, Ugo
Wang, Yan
Yamazaki, Kazuya
Johansson, Mikael P.
Quantum Physics
Quantum computing (QC) has gained significant attention over the past two decades due to its potential for speeding up classically demanding tasks. This transition from an academic focus to a thriving commercial sector is reflected in substantial global investments. While advancements in qubit counts and functionalities continues at a rapid pace, current quantum systems still lack the scalability for practical applications, facing challenges such as too high error rates and limited coherence times. This perspective paper examines the relationship between QC and high-performance computing (HPC), highlighting their complementary roles in enhancing computational efficiency. It is widely acknowledged that even fully error-corrected QCs will not be suited for all computational task. Rather, future compute infrastructures are anticipated to employ quantum acceleration within hybrid systems that integrate HPC and QC. While QCs can enhance classical computing, traditional HPC remains essential for maximizing quantum acceleration. This integration is a priority for supercomputing centers and companies, sparking innovation to address the challenges of merging these technologies. The Accelerated Data Analytics and Computing Institute (ADAC) is comprised of globally leading HPC centers. ADAC has established a Quantum Computing Working Group to promote and catalyze collaboration among its members. This paper synthesizes insights from the QC Working Group, supplemented by findings from a member survey detailing ongoing projects and strategic directions. By outlining the current landscape and challenges of QC integration into HPC ecosystems, this work aims to provide HPC specialists with a deeper understanding of QC and its future implications for computationally intensive endeavors.
title The Role of Quantum Computing in Advancing Scientific High-Performance Computing: A perspective from the ADAC Institute
topic Quantum Physics
url https://arxiv.org/abs/2508.11765