Related papers: Accurate machine learning force fields via experimental and simulation data fusion

Accurate machine learning force fields via experimental and simulation data fusion

URL: http://arxiv.org/abs/2308.09142v1
Date: Thu, 17 Aug 2023 18:22:19 GMT
Title: Accurate machine learning force fields via experimental and simulation data fusion
Authors: Sebastien R\"ocken and Julija Zavadlav
Abstract summary: Machine Learning (ML)-based force fields are attracting ever-increasing interest due to their capacity to span scales of classical interatomic potentials at quantum-level accuracy. Here we leverage both Density Functional Theory (DFT) calculations and experimentally measured mechanical properties and lattice parameters to train an ML potential of titanium. We demonstrate that the fused data learning strategy can concurrently satisfy all target objectives, thus resulting in a molecular model of higher accuracy compared to the models trained with a single source data.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Machine Learning (ML)-based force fields are attracting ever-increasing interest due to their capacity to span spatiotemporal scales of classical interatomic potentials at quantum-level accuracy. They can be trained based on high-fidelity simulations or experiments, the former being the common case. However, both approaches are impaired by scarce and erroneous data resulting in models that either do not agree with well-known experimental observations or are under-constrained and only reproduce some properties. Here we leverage both Density Functional Theory (DFT) calculations and experimentally measured mechanical properties and lattice parameters to train an ML potential of titanium. We demonstrate that the fused data learning strategy can concurrently satisfy all target objectives, thus resulting in a molecular model of higher accuracy compared to the models trained with a single data source. The inaccuracies of DFT functionals at target experimental properties were corrected, while the investigated off-target properties remained largely unperturbed. Our approach is applicable to any material and can serve as a general strategy to obtain highly accurate ML potentials.

Related papers

Multi-task learning for molecular electronic structure approaching coupled-cluster accuracy [9.81014501502049]
We develop a unified machine learning method for electronic structures of organic molecules using the gold-standard CCSD(T) calculations as training data. Tested on hydrocarbon molecules, our model outperforms DFT with the widely-used hybrid and double hybrid functionals in computational costs and prediction accuracy of various quantum chemical properties.
arXiv Detail & Related papers (2024-05-09T19:51:27Z)
Self-Consistency Training for Density-Functional-Theory Hamiltonian Prediction [74.84850523400873]
We show that Hamiltonian prediction possesses a self-consistency principle, based on which we propose self-consistency training. It enables the model to be trained on a large amount of unlabeled data, hence addresses the data scarcity challenge. It is more efficient than running DFT to generate labels for supervised training, since it amortizes DFT calculation over a set of queries.
arXiv Detail & Related papers (2024-03-14T16:52:57Z)
Discovering Interpretable Physical Models using Symbolic Regression and Discrete Exterior Calculus [55.2480439325792]
We propose a framework that combines Symbolic Regression (SR) and Discrete Exterior Calculus (DEC) for the automated discovery of physical models. DEC provides building blocks for the discrete analogue of field theories, which are beyond the state-of-the-art applications of SR to physical problems. We prove the effectiveness of our methodology by re-discovering three models of Continuum Physics from synthetic experimental data.
arXiv Detail & Related papers (2023-10-10T13:23:05Z)
Machine learning enabled experimental design and parameter estimation for ultrafast spin dynamics [54.172707311728885]
We introduce a methodology that combines machine learning with Bayesian optimal experimental design (BOED) Our method employs a neural network model for large-scale spin dynamics simulations for precise distribution and utility calculations in BOED. Our numerical benchmarks demonstrate the superior performance of our method in guiding XPFS experiments, predicting model parameters, and yielding more informative measurements within limited experimental time.
arXiv Detail & Related papers (2023-06-03T06:19:20Z)
Capturing dynamical correlations using implicit neural representations [85.66456606776552]
We develop an artificial intelligence framework which combines a neural network trained to mimic simulated data from a model Hamiltonian with automatic differentiation to recover unknown parameters from experimental data. In doing so, we illustrate the ability to build and train a differentiable model only once, which then can be applied in real-time to multi-dimensional scattering data.
arXiv Detail & Related papers (2023-04-08T07:55:36Z)
Evaluating the Transferability of Machine-Learned Force Fields for Material Property Modeling [2.494740426749958]
We present a more comprehensive set of benchmarking tests for evaluating the transferability of machine-learned force fields. We use a graph neural network (GNN)-based force field coupled with the OpenMM package to carry out MD simulations for Argon. Our results show that the model can accurately capture the behavior of the solid phase only when the configurations from the solid phase are included in the training dataset.
arXiv Detail & Related papers (2023-01-10T00:25:48Z)
NeuralNEB -- Neural Networks can find Reaction Paths Fast [7.7365628406567675]
Quantum mechanical methods like Density Functional Theory (DFT) are used with great success alongside efficient search algorithms for studying kinetics of reactive systems. Machine Learning (ML) models have turned out to be excellent emulators of small molecule DFT calculations and could possibly replace DFT in such tasks. In this paper we train state of the art equivariant Graph Neural Network (GNN)-based models on around 10.000 elementary reactions from the Transition1x dataset.
arXiv Detail & Related papers (2022-07-20T15:29:45Z)
Prediction of liquid fuel properties using machine learning models with Gaussian processes and probabilistic conditional generative learning [56.67751936864119]
The present work aims to construct cheap-to-compute machine learning (ML) models to act as closure equations for predicting the physical properties of alternative fuels. Those models can be trained using the database from MD simulations and/or experimental measurements in a data-fusion-fidelity approach. The results show that ML models can predict accurately the fuel properties of a wide range of pressure and temperature conditions.
arXiv Detail & Related papers (2021-10-18T14:43:50Z)
BIGDML: Towards Exact Machine Learning Force Fields for Materials [55.944221055171276]
Machine-learning force fields (MLFF) should be accurate, computationally and data efficient, and applicable to molecules, materials, and interfaces thereof. Here, we introduce the Bravais-Inspired Gradient-Domain Machine Learning approach and demonstrate its ability to construct reliable force fields using a training set with just 10-200 atoms.
arXiv Detail & Related papers (2021-06-08T10:14:57Z)
Automated discovery of a robust interatomic potential for aluminum [4.6028828826414925]
Machine learning (ML) based potentials aim for faithful emulation of quantum mechanics (QM) calculations at drastically reduced computational cost. We present a highly automated approach to dataset construction using the principles of active learning (AL) We demonstrate this approach by building an ML potential for aluminum (ANI-Al) To demonstrate transferability, we perform a 1.3M atom shock simulation, and show that ANI-Al predictions agree very well with DFT calculations on local atomic environments sampled from the nonequilibrium dynamics.
arXiv Detail & Related papers (2020-03-10T19:06:32Z)
Embedded-physics machine learning for coarse-graining and collective variable discovery without data [3.222802562733787]
We present a novel learning framework that consistently embeds underlying physics. We propose a novel objective based on reverse Kullback-Leibler divergence that fully incorporates the available physics in the form of the atomistic force field. We demonstrate the algorithmic advances in terms of predictive ability and the physical meaning of the revealed CVs for a bimodal potential energy function and the alanine dipeptide.
arXiv Detail & Related papers (2020-02-24T10:28:41Z)

This list is automatically generated from the titles and abstracts of the papers in this site.