Quantum-centric Supercomputing for Materials Science: A Perspective on Challenges and Future Directions
- URL: http://arxiv.org/abs/2312.09733v2
- Date: Thu, 12 Sep 2024 22:23:31 GMT
- Title: Quantum-centric Supercomputing for Materials Science: A Perspective on Challenges and Future Directions
- Authors: Yuri Alexeev, Maximilian Amsler, Paul Baity, Marco Antonio Barroca, Sanzio Bassini, Torey Battelle, Daan Camps, David Casanova, Young Jai Choi, Frederic T. Chong, Charles Chung, Chris Codella, Antonio D. Corcoles, James Cruise, Alberto Di Meglio, Jonathan Dubois, Ivan Duran, Thomas Eckl, Sophia Economou, Stephan Eidenbenz, Bruce Elmegreen, Clyde Fare, Ismael Faro, Cristina Sanz Fernández, Rodrigo Neumann Barros Ferreira, Keisuke Fuji, Bryce Fuller, Laura Gagliardi, Giulia Galli, Jennifer R. Glick, Isacco Gobbi, Pranav Gokhale, Salvador de la Puente Gonzalez, Johannes Greiner, Bill Gropp, Michele Grossi, Emanuel Gull, Burns Healy, Benchen Huang, Travis S. Humble, Nobuyasu Ito, Artur F. Izmaylov, Ali Javadi-Abhari, Douglas Jennewein, Shantenu Jha, Liang Jiang, Barbara Jones, Wibe Albert de Jong, Petar Jurcevic, William Kirby, Stefan Kister, Masahiro Kitagawa, Joel Klassen, Katherine Klymko, Kwangwon Koh, Masaaki Kondo, Doga Murat Kurkcuoglu, Krzysztof Kurowski, Teodoro Laino, Ryan Landfield, Matt Leininger, Vicente Leyton-Ortega, Ang Li, Meifeng Lin, Junyu Liu, Nicolas Lorente, Andre Luckow, Simon Martiel, Francisco Martin-Fernandez, Margaret Martonosi, Claire Marvinney, Arcesio Castaneda Medina, Dirk Merten, Antonio Mezzacapo, Kristel Michielsen, Abhishek Mitra, Tushar Mittal, Kyungsun Moon, Joel Moore, Mario Motta, Young-Hye Na, Yunseong Nam, Prineha Narang, Yu-ya Ohnishi, Daniele Ottaviani, Matthew Otten, Scott Pakin, Vincent R. Pascuzzi, Ed Penault, Tomasz Piontek, Jed Pitera, Patrick Rall, Gokul Subramanian Ravi, Niall Robertson, Matteo Rossi, Piotr Rydlichowski, Hoon Ryu, Georgy Samsonidze, Mitsuhisa Sato, Nishant Saurabh, Vidushi Sharma, Kunal Sharma, Soyoung Shin, George Slessman, Mathias Steiner, Iskandar Sitdikov, In-Saeng Suh, Eric Switzer, Wei Tang, Joel Thompson, Synge Todo, Minh Tran, Dimitar Trenev, Christian Trott, Huan-Hsin Tseng, Esin Tureci, David García Valinas, Sofia Vallecorsa, Christopher Wever, Konrad Wojciechowski, Xiaodi Wu, Shinjae Yoo, Nobuyuki Yoshioka, Victor Wen-zhe Yu, Seiji Yunoki, Sergiy Zhuk, Dmitry Zubarev,
- Abstract summary: Hard computational tasks in materials science stretch the limits of existing high-performance supercomputing centers.
Quantum computing, on the other hand, is an emerging technology with the potential to accelerate many of the computational tasks needed for materials science.
- Score: 20.785521465797203
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Computational models are an essential tool for the design, characterization, and discovery of novel materials. Hard computational tasks in materials science stretch the limits of existing high-performance supercomputing centers, consuming much of their simulation, analysis, and data resources. Quantum computing, on the other hand, is an emerging technology with the potential to accelerate many of the computational tasks needed for materials science. In order to do that, the quantum technology must interact with conventional high-performance computing in several ways: approximate results validation, identification of hard problems, and synergies in quantum-centric supercomputing. In this paper, we provide a perspective on how quantum-centric supercomputing can help address critical computational problems in materials science, the challenges to face in order to solve representative use cases, and new suggested directions.
Related papers
- A Review of Quantum Scientific Computing Algorithms for Engineering Problems [0.0]
Quantum computing, leveraging quantum phenomena like superposition and entanglement, is emerging as a transformative force in computing technology.
This paper systematically explores the foundational concepts of quantum mechanics and their implications for computational advancements.
arXiv Detail & Related papers (2024-08-25T21:40:22Z) - From Graphs to Qubits: A Critical Review of Quantum Graph Neural Networks [56.51893966016221]
Quantum Graph Neural Networks (QGNNs) represent a novel fusion of quantum computing and Graph Neural Networks (GNNs)
This paper critically reviews the state-of-the-art in QGNNs, exploring various architectures.
We discuss their applications across diverse fields such as high-energy physics, molecular chemistry, finance and earth sciences, highlighting the potential for quantum advantage.
arXiv Detail & Related papers (2024-08-12T22:53:14Z) - Assessing and Advancing the Potential of Quantum Computing: A NASA Case Study [11.29246196323319]
We describe NASA's work in assessing and advancing the potential of quantum computing.
We discuss advances in algorithms, both near- and longer-term, and the results of our explorations on current hardware and with simulations.
This work also includes physics-inspired classical algorithms that can be used at application scale today.
arXiv Detail & Related papers (2024-06-21T19:05:42Z) - Quantifying fault tolerant simulation of strongly correlated systems using the Fermi-Hubbard model [31.805673346157665]
Building a holistic understanding of strongly correlated materials is critical.
Fault-tolerant quantum computers have been proposed as a path forward to overcome these difficulties.
We estimate the resource costs needed to use fault-tolerant quantum computers for obtaining experimentally relevant quantities.
arXiv Detail & Related papers (2024-06-10T17:50:56Z) - Quantum Computing: Vision and Challenges [16.50566018023275]
We discuss cutting-edge developments in quantum computer hardware advancement and subsequent advances in quantum cryptography, quantum software, and high-scalability quantum computers.
Many potential challenges and exciting new trends for quantum technology research and development are highlighted in this paper for a broader debate.
arXiv Detail & Related papers (2024-03-04T17:33:18Z) - Quantum Computing for High-Energy Physics: State of the Art and
Challenges. Summary of the QC4HEP Working Group [33.8590861326926]
This paper is led by CERN, DESY and IBM and provides the status of high-energy physics quantum computations.
We give examples for theoretical and experimental target benchmark applications, which can be addressed in the near future.
Having the IBM 100 x 100 challenge in mind, where possible, we also provide resource estimates for the examples given using error mitigated quantum computing.
arXiv Detail & Related papers (2023-07-06T18:01:02Z) - Reliable AI: Does the Next Generation Require Quantum Computing? [71.84486326350338]
We show that digital hardware is inherently constrained in solving problems about optimization, deep learning, or differential equations.
In contrast, analog computing models, such as the Blum-Shub-Smale machine, exhibit the potential to surmount these limitations.
arXiv Detail & Related papers (2023-07-03T19:10:45Z) - Quantum Machine Learning: from physics to software engineering [58.720142291102135]
We show how classical machine learning approach can help improve the facilities of quantum computers.
We discuss how quantum algorithms and quantum computers may be useful for solving classical machine learning tasks.
arXiv Detail & Related papers (2023-01-04T23:37:45Z) - Quantum-tailored machine-learning characterization of a superconducting
qubit [50.591267188664666]
We develop an approach to characterize the dynamics of a quantum device and learn device parameters.
This approach outperforms physics-agnostic recurrent neural networks trained on numerically generated and experimental data.
This demonstration shows how leveraging domain knowledge improves the accuracy and efficiency of this characterization task.
arXiv Detail & Related papers (2021-06-24T15:58:57Z) - Simulating Quantum Materials with Digital Quantum Computers [55.41644538483948]
Digital quantum computers (DQCs) can efficiently perform quantum simulations that are otherwise intractable on classical computers.
The aim of this review is to provide a summary of progress made towards achieving physical quantum advantage.
arXiv Detail & Related papers (2021-01-21T20:10:38Z) - An Application of Quantum Annealing Computing to Seismic Inversion [55.41644538483948]
We apply a quantum algorithm to a D-Wave quantum annealer to solve a small scale seismic inversions problem.
The accuracy achieved by the quantum computer is at least as good as that of the classical computer.
arXiv Detail & Related papers (2020-05-06T14:18:44Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.