Your search keyword '"Artrith, Nongnuch"' showing total 7 results

1. ænet-PyTorch: A GPU-supported implementation for machine learning atomic potentials training.

Author

López-Zorrilla, Jon, Aretxabaleta, Xabier M., Yeu, In Won, Etxebarria, Iñigo, Manzano, Hegoi, and Artrith, Nongnuch

Subjects

MACHINE learning, CENTRAL processing units, NUCLEAR energy, FORCE & energy, SMALL molecules, GRAPHICS processing units

Abstract

In this work, we present ænet-PyTorch, a PyTorch-based implementation for training artificial neural network-based machine learning interatomic potentials. Developed as an extension of the atomic energy network (ænet), ænet-PyTorch provides access to all the tools included in ænet for the application and usage of the potentials. The package has been designed as an alternative to the internal training capabilities of ænet, leveraging the power of graphic processing units to facilitate direct training on forces in addition to energies. This leads to a substantial reduction of the training time by one to two orders of magnitude compared to the central processing unit implementation, enabling direct training on forces for systems beyond small molecules. Here, we demonstrate the main features of ænet-PyTorch and show its performance on open databases. Our results show that training on all the force information within a dataset is not necessary, and including between 10% and 20% of the force information is sufficient to achieve optimally accurate interatomic potentials with the least computational resources. [ABSTRACT FROM AUTHOR]

Published

2023

2. ænet-PyTorch: A GPU-supported implementation for machine learning atomic potentials training

Author

Sub Materials Chemistry and Catalysis, Materials Chemistry and Catalysis, López-Zorrilla, Jon, Aretxabaleta, Xabier M., Yeu, In Won, Etxebarria, Iñigo, Manzano, Hegoi, Artrith, Nongnuch, Sub Materials Chemistry and Catalysis, Materials Chemistry and Catalysis, López-Zorrilla, Jon, Aretxabaleta, Xabier M., Yeu, In Won, Etxebarria, Iñigo, Manzano, Hegoi, and Artrith, Nongnuch

Published

2023

3. AENET–LAMMPS and AENET–TINKER: Interfaces for accurate and efficient molecular dynamics simulations with machine learning potentials.

Author

Chen, Michael S., Morawietz, Tobias, Mori, Hideki, Markland, Thomas E., and Artrith, Nongnuch

Subjects

MOLECULAR dynamics, MONTE Carlo method, MACHINE dynamics, MACHINE learning, NUCLEAR energy

Abstract

Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles methods can approach the accuracy of the reference method at a fraction of the computational cost. To facilitate efficient MLP-based molecular dynamics and Monte Carlo simulations, an integration of the MLPs with sampling software is needed. Here, we develop two interfaces that link the atomic energy network (ænet) MLP package with the popular sampling packages TINKER and LAMMPS. The three packages, ænet, TINKER, and LAMMPS, are free and open-source software that enable, in combination, accurate simulations of large and complex systems with low computational cost that scales linearly with the number of atoms. Scaling tests show that the parallel efficiency of the ænet–TINKER interface is nearly optimal but is limited to shared-memory systems. The ænet–LAMMPS interface achieves excellent parallel efficiency on highly parallel distributed-memory systems and benefits from the highly optimized neighbor list implemented in LAMMPS. We demonstrate the utility of the two MLP interfaces for two relevant example applications: the investigation of diffusion phenomena in liquid water and the equilibration of nanostructured amorphous battery materials. [ABSTRACT FROM AUTHOR]

Published

2021

4. Data-driven approach to parameterize SCAN+U for an accurate description of 3d transition metal oxide thermochemistry

Author

Artrith, Nongnuch, Garrido Torres, José Antonio, Urban, Alexander, Hybertsen, Mark S., Artrith, Nongnuch, Garrido Torres, José Antonio, Urban, Alexander, and Hybertsen, Mark S.

Published

2022

5. Constructing first-principles phase diagrams of amorphous Li<italic>x</italic>Si using machine-learning-assisted sampling with an evolutionary algorithm.

Author

Artrith, Nongnuch, Urban, Alexander, and Ceder, Gerbrand

Subjects

*PHASE diagrams, *AMORPHOUS substances, *MACHINE learning, *EVOLUTIONARY algorithms, *STATISTICAL sampling

Abstract

The atomistic modeling of amorphous materials requires structure sizes and sampling statistics that are challenging to achieve with first-principles methods. Here, we propose a methodology to speed up the sampling of amorphous and disordered materials using a combination of a genetic algorithm and a specialized machine-learning potential based on artificial neural networks (ANNs). We show for the example of the amorphous LiSi alloy that around 1000 first-principles calculations are sufficient for the ANN-potential assisted sampling of low-energy atomic configurations in the entire amorphous LixSi phase space. The obtained phase diagram is validated by comparison with the results from an extensive sampling of LixSi configurations using molecular dynamics simulations and a general ANN potential trained to ∼45 000 first-principles calculations. This demonstrates the utility of the approach for the first-principles modeling of amorphous materials. [ABSTRACT FROM AUTHOR]

Published

2018

6. Construction of high-dimensional neural network potentials using environment-dependent atom pairs.

Author

Jose, K. V. Jovan, Artrith, Nongnuch, and Behler, Jörg

Subjects

*ARTIFICIAL neural networks, *POTENTIAL theory (Physics), *COMPUTER simulation, *CHEMICAL processes, *MOLECULAR dynamics, *POTENTIAL energy surfaces, *COMPLEXITY (Philosophy)

Abstract

An accurate determination of the potential energy is the crucial step in computer simulations of chemical processes, but using electronic structure methods on-the-fly in molecular dynamics (MD) is computationally too demanding for many systems. Constructing more efficient interatomic potentials becomes intricate with increasing dimensionality of the potential-energy surface (PES), and for numerous systems the accuracy that can be achieved is still not satisfying and far from the reliability of first-principles calculations. Feed-forward neural networks (NNs) have a very flexible functional form, and in recent years they have been shown to be an accurate tool to construct efficient PESs. High-dimensional NN potentials based on environment-dependent atomic energy contributions have been presented for a number of materials. Still, these potentials may be improved by a more detailed structural description, e.g., in form of atom pairs, which directly reflect the atomic interactions and take the chemical environment into account. We present an implementation of an NN method based on atom pairs, and its accuracy and performance are compared to the atom-based NN approach using two very different systems, the methanol molecule and metallic copper. We find that both types of NN potentials provide an excellent description of both PESs, with the pair-based method yielding a slightly higher accuracy making it a competitive alternative for addressing complex systems in MD simulations. [ABSTRACT FROM AUTHOR]

Published

2012

7. Constructing first-principles phase diagrams of amorphous Li x Si using machine-learning-assisted sampling with an evolutionary algorithm.

Author

Artrith N, Urban A, and Ceder G

Abstract

The atomistic modeling of amorphous materials requires structure sizes and sampling statistics that are challenging to achieve with first-principles methods. Here, we propose a methodology to speed up the sampling of amorphous and disordered materials using a combination of a genetic algorithm and a specialized machine-learning potential based on artificial neural networks (ANNs). We show for the example of the amorphous LiSi alloy that around 1000 first-principles calculations are sufficient for the ANN-potential assisted sampling of low-energy atomic configurations in the entire amorphous Li x Si phase space. The obtained phase diagram is validated by comparison with the results from an extensive sampling of Li x Si configurations using molecular dynamics simulations and a general ANN potential trained to ∼45 000 first-principles calculations. This demonstrates the utility of the approach for the first-principles modeling of amorphous materials.

Published

2018