TY - GEN
T1 - Machine-Learning Accelerated Studies of Materials with High Performance and Edge Computing
AU - Li, Ying Wai
AU - Doak, Peter W.
AU - Balduzzi, Giovanni
AU - Elwasif, Wael
AU - D’Azevedo, Ed F.
AU - Maier, Thomas A.
N1 - Publisher Copyright:
© 2022, Springer Nature Switzerland AG.
PY - 2022
Y1 - 2022
N2 - In the studies of materials, experimental measurements often serve as the reference to verify physics theory and modeling; while theory and modeling provide a fundamental understanding of the physics and principles behind. However, the interactions and cross validation between them have long been a challenge even to-date. Not only that inferring a physics model from experimental data is itself a difficult inverse problem, another major challenge is the orders-of-magnitude longer wall-clock time required to carry out high-fidelity computer modeling to match the timescale of experiments. We envisage that by combining high performance computing, data science, and edge computing technology, the current predicament can be alleviated, and a new paradigm of data-driven physics research will open up. For example, we can accelerate computer simulations by first performing the large-scale modeling on high performance computers and train a machine-learned surrogate model. This computationally inexpensive surrogate model can then be transferred to the computing units residing closely to the experimental facilities to perform high-fidelity simulations at a much higher throughout. The model will also be more amenable to analyzing and validating experimental observations in comparable time scales at a much lower computational cost. Further integration of these accelerated computer simulations with an outer machine learning loop can also inform and direct future experiments, while making the inverse problem of physics model inference more tractable. We will demonstrate a proof-of-concept by using a quantum Monte Carlo application, Dynamical Cluster Approximation (DCA++), to machine-learn a surrogate model and accelerate the study of quantum correlated materials.
AB - In the studies of materials, experimental measurements often serve as the reference to verify physics theory and modeling; while theory and modeling provide a fundamental understanding of the physics and principles behind. However, the interactions and cross validation between them have long been a challenge even to-date. Not only that inferring a physics model from experimental data is itself a difficult inverse problem, another major challenge is the orders-of-magnitude longer wall-clock time required to carry out high-fidelity computer modeling to match the timescale of experiments. We envisage that by combining high performance computing, data science, and edge computing technology, the current predicament can be alleviated, and a new paradigm of data-driven physics research will open up. For example, we can accelerate computer simulations by first performing the large-scale modeling on high performance computers and train a machine-learned surrogate model. This computationally inexpensive surrogate model can then be transferred to the computing units residing closely to the experimental facilities to perform high-fidelity simulations at a much higher throughout. The model will also be more amenable to analyzing and validating experimental observations in comparable time scales at a much lower computational cost. Further integration of these accelerated computer simulations with an outer machine learning loop can also inform and direct future experiments, while making the inverse problem of physics model inference more tractable. We will demonstrate a proof-of-concept by using a quantum Monte Carlo application, Dynamical Cluster Approximation (DCA++), to machine-learn a surrogate model and accelerate the study of quantum correlated materials.
KW - Correlated materials
KW - Edge computing
KW - Machine learning
KW - Quantum Monte Carlo
UR - http://www.scopus.com/inward/record.url?scp=85127064960&partnerID=8YFLogxK
U2 - 10.1007/978-3-030-96498-6_11
DO - 10.1007/978-3-030-96498-6_11
M3 - Conference contribution
AN - SCOPUS:85127064960
SN - 9783030964979
T3 - Communications in Computer and Information Science
SP - 190
EP - 205
BT - Driving Scientific and Engineering Discoveries Through the Integration of Experiment, Big Data, and Modeling and Simulation - 21st Smoky Mountains Computational Sciences and Engineering, SMC 2021, Revised Selected Papers
A2 - Nichols, [given-name]Jeffrey
A2 - Maccabe, [given-name]Arthur ‘Barney’
A2 - Nutaro, James
A2 - Pophale, Swaroop
A2 - Devineni, Pravallika
A2 - Ahearn, Theresa
A2 - Verastegui, Becky
PB - Springer Science and Business Media Deutschland GmbH
T2 - 21st Smoky Mountains Computational Sciences and Engineering Conference, SMC 2021
Y2 - 18 October 2021 through 20 October 2021
ER -