Machine learning takes materials modeling into new era
Deep learning approach enables accurate electronic structure calculations
at large scales
Date:
July 7, 2023
Source:
Helmholtz-Zentrum Dresden-Rossendorf
Summary:
The arrangement of electrons in matter, known as the electronic
structure, plays a crucial role in fundamental but also applied
research such as drug design and energy storage. However, the
lack of a simulation technique that offers both high fidelity and
scalability across different time and length scales has long been
a roadblock for the progress of these technologies. Researchers
have now pioneered a machine learning- based simulation method
that supersedes traditional electronic structure simulation
techniques. Their Materials Learning Algorithms (MALA) software
stack enables access to previously unattainable length scales.
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FULL STORY ==========================================================================
The arrangement of electrons in matter, known as the electronic structure, plays a crucial role in fundamental but also applied research such as drug design and energy storage. However, the lack of a simulation technique
that offers both high fidelity and scalability across different time
and length scales has long been a roadblock for the progress of these technologies.
Researchers from the Center for Advanced Systems Understanding (CASUS)
at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR) in Go"rlitz, Germany,
and Sandia National Laboratories in Albuquerque, New Mexico, USA, have now pioneered a machine learning-based simulation method (npj Computational Materials), that supersedes traditional electronic structure simulation techniques. Their Materials Learning Algorithms (MALA) software stack
enables access to previously unattainable length scales.
Electrons are elementary particles of fundamental importance. Their
quantum mechanical interactions with one another and with atomic nuclei
give rise to a multitude of phenomena observed in chemistry and materials science.
Understanding and controlling the electronic structure of matter provides insights into the reactivity of molecules, the structure and energy
transport within planets, and the mechanisms of material failure.
Scientific challenges are increasingly being addressed through
computational modeling and simulation, leveraging the capabilities of high-performance computing. However, a significant obstacle to achieving realistic simulations with quantum precision is the lack of a predictive modeling technique that combines high accuracy with scalability across different length and time scales. Classical atomistic simulation methods
can handle large and complex systems, but their omission of quantum
electronic structure restricts their applicability. Conversely, simulation methods which do not rely on assumptions such as empirical modeling and parameter fitting (first principles methods) provide high fidelity but
are computationally demanding. For instance, density functional theory
(DFT), a widely used first principles method, exhibits cubic scaling with system size, thus restricting its predictive capabilities to small scales.
Hybrid approach based on deep learning The team of researchers now
presented a novel simulation method called the Materials Learning
Algorithms (MALA) software stack. In computer science, a software stack
is a collection of algorithms and software components that are combined
to create a software application for solving a particular problem.
Lenz Fiedler, a Ph.D. student and key developer of MALA at CASUS,
explains, "MALA integrates machine learning with physics-based approaches
to predict the electronic structure of materials. It employs a hybrid
approach, utilizing an established machine learning method called deep
learning to accurately predict local quantities, complemented by physics algorithms for computing global quantities of interest." The MALA
software stack takes the arrangement of atoms in space as input and
generates fingerprints known as bispectrum components, which encode the
spatial arrangement of atoms around a Cartesian grid point. The machine learning model in MALA is trained to predict the electronic structure
based on this atomic neighborhood. A significant advantage of MALA is its machine learning model's ability to be independent of the system size,
allowing it to be trained on data from small systems and deployed at
any scale.
In their publication, the team of researchers showcased the remarkable effectiveness of this strategy. They achieved a speedup of over 1,000
times for smaller system sizes, consisting of up to a few thousand
atoms, compared to conventional algorithms. Furthermore, the team
demonstrated MALA's capability to accurately perform electronic structure calculations at a large scale, involving over 100,000 atoms. Notably,
this accomplishment was achieved with modest computational effort,
revealing the limitations of conventional DFT codes.
Attila Cangi, the Acting Department Head of Matter under Extreme
Conditions at CASUS, explains: "As the system size increases and more
atoms are involved, DFT calculations become impractical, whereas MALA's
speed advantage continues to grow. The key breakthrough of MALA lies in
its capability to operate on local atomic environments, enabling accurate numerical predictions that are minimally affected by system size. This groundbreaking achievement opens up computational possibilities that
were once considered unattainable." Boost for applied research expected
Cangi aims to push the boundaries of electronic structure calculations
by leveraging machine learning: "We anticipate that MALA will spark a transformation in electronic structure calculations, as we now have a
method to simulate significantly larger systems at an unprecedented
speed. In the future, researchers will be able to address a broad
range of societal challenges based on a significantly improved baseline, including developing new vaccines and novel materials for energy storage, conducting large-scale simulations of semiconductor devices, studying
material defects, and exploring chemical reactions for converting
the atmospheric greenhouse gas carbon dioxide into climate-friendly
minerals." Furthermore, MALA's approach is particularly suited for high-performance computing (HPC). As the system size grows, MALA enables independent processing on the computational grid it utilizes, effectively leveraging HPC resources, particularly graphical processing units. Siva Rajamanickam, a staff scientist and expert in parallel computing at the
Sandia National Laboratories, explains, "MALA's algorithm for electronic structure calculations maps well to modern HPC systems with distributed accelerators. The capability to decompose work and execute in parallel different grid points across different accelerators makes MALA an
ideal match for scalable machine learning on HPC resources, leading to unparalleled speed and efficiency in electronic structure calculations."
Apart from the developing partners HZDR and Sandia National Laboratories,
MALA is already employed by institutions and companies such as the
Georgia Institute of Technology, the North Carolina A&T State University, Sambanova Systems Inc., and Nvidia Corp.
* RELATED_TOPICS
o Matter_&_Energy
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o Circuit_design o Supercomputer o Computer_software o
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========================================================================== Journal Reference:
1. Lenz Fiedler, Normand A. Modine, Steve Schmerler, Dayton J. Vogel,
Gabriel A. Popoola, Aidan P. Thompson, Sivasankaran Rajamanickam,
Attila Cangi. Predicting electronic structures at any length scale
with machine learning. npj Computational Materials, 2023; 9 (1)
DOI: 10.1038/s41524- 023-01070-z ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2023/07/230707111625.htm
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