Related papers: Learning force laws in many-body systems

Learning force laws in many-body systems

URL: http://arxiv.org/abs/2310.05273v2
Date: Tue, 10 Sep 2024 03:35:36 GMT
Title: Learning force laws in many-body systems
Authors: Wentao Yu, Eslam Abdelaleem, Ilya Nemenman, Justin C. Burton,
Abstract summary: We show how a machine learning model can infer force laws in dusty plasma. The model accounts for inherent symmetries, non-identical particles, and learns the effective non-reciprocal forces between particles with exquisite accuracy. Our ability to identify new physics from experimental data demonstrates how ML-powered approaches can guide new routes of scientific discovery in many-body systems.
Score: 2.185577978806931
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Scientific laws describing natural systems may be more complex than our intuition can handle, thus how we discover laws must change. Machine learning (ML) models can analyze large quantities of data, but their structure should match the underlying physical constraints to provide useful insight. While progress has been made using simulated data where the underlying physics is known, training and validating ML models on experimental data requires fundamentally new approaches. Here we demonstrate and experimentally validate an ML approach that incorporates physical intuition to infer force laws in dusty plasma, a complex, many-body system. Trained on 3D particle trajectories, the model accounts for inherent symmetries, non-identical particles, and learns the effective non-reciprocal forces between particles with exquisite accuracy (R^2>0.99). We validate the model by inferring particle masses in two independent yet consistent ways. The model's accuracy enables precise measurements of particle charge and screening length, discovering violations of common theoretical assumptions. Our ability to identify new physics from experimental data demonstrates how ML-powered approaches can guide new routes of scientific discovery in many-body systems. Furthermore, we anticipate our ML approach to be a starting point for inferring laws from dynamics in a wide range of many-body systems, from colloids to living organisms.

Related papers

Scientific Machine Learning Seismology [0.0]
Scientific machine learning (SciML) is an interdisciplinary research field that integrates machine learning, particularly deep learning, with physics theory to understand and predict complex natural phenomena. PINNs and neural operators (NOs) are two popular methods for SciML. The use of PINNs is expanding into areas such as simultaneous solutions of differential equations, inference in underdetermined systems, and regularization based on physics.
arXiv Detail & Related papers (2024-09-27T02:27:42Z)
Large language models, physics-based modeling, experimental measurements: the trinity of data-scarce learning of polymer properties [10.955525128731654]
Large language models (LLMs) bear promise as a fast and accurate material modeling paradigm for evaluation, analysis, and design. We present a physics-based training pipeline that tackles the pathology of data scarcity.
arXiv Detail & Related papers (2024-07-03T02:57:40Z)
A Multi-Grained Symmetric Differential Equation Model for Learning Protein-Ligand Binding Dynamics [74.93549765488103]
In drug discovery, molecular dynamics simulation provides a powerful tool for predicting binding affinities, estimating transport properties, and exploring pocket sites. We propose NeuralMD, the first machine learning surrogate that can facilitate numerical MD and provide accurate simulations in protein-ligand binding. We show the efficiency and effectiveness of NeuralMD, with a 2000$times$ speedup over standard numerical MD simulation and outperforming all other ML approaches by up to 80% under the stability metric.
arXiv Detail & Related papers (2024-01-26T09:35:17Z)
Accurate machine learning force fields via experimental and simulation data fusion [0.0]
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.
arXiv Detail & Related papers (2023-08-17T18:22:19Z)
Learning Neural Constitutive Laws From Motion Observations for Generalizable PDE Dynamics [97.38308257547186]
Many NN approaches learn an end-to-end model that implicitly models both the governing PDE and material models. We argue that the governing PDEs are often well-known and should be explicitly enforced rather than learned. We introduce a new framework termed "Neural Constitutive Laws" (NCLaw) which utilizes a network architecture that strictly guarantees standard priors.
arXiv Detail & Related papers (2023-04-27T17:42:24Z)
Physics-informed Information Field Theory for Modeling Physical Systems with Uncertainty Quantification [0.0]
Information field theory (IFT) provides the tools necessary to perform statistics over fields that are not necessarily Gaussian. We extend IFT to physics-informed IFT (PIFT) by encoding the functional priors with information about the physical laws which describe the field. The posteriors derived from this PIFT remain independent of any numerical scheme and can capture multiple modes. We numerically demonstrate that the method correctly identifies when the physics cannot be trusted, in which case it automatically treats learning the field as a regression problem.
arXiv Detail & Related papers (2023-01-18T15:40:19Z)
NeuroFluid: Fluid Dynamics Grounding with Particle-Driven Neural Radiance Fields [65.07940731309856]
Deep learning has shown great potential for modeling the physical dynamics of complex particle systems such as fluids. In this paper, we consider a partially observable scenario known as fluid dynamics grounding. We propose a differentiable two-stage network named NeuroFluid. It is shown to reasonably estimate the underlying physics of fluids with different initial shapes, viscosity, and densities.
arXiv Detail & Related papers (2022-03-03T15:13:29Z)
Scalable approach to many-body localization via quantum data [69.3939291118954]
Many-body localization is a notoriously difficult phenomenon from quantum many-body physics. We propose a flexible neural network based learning approach that circumvents any computationally expensive step. Our approach can be applied to large-scale quantum experiments to provide new insights into quantum many-body physics.
arXiv Detail & Related papers (2022-02-17T19:00:09Z)
Learning continuous models for continuous physics [94.42705784823997]
We develop a test based on numerical analysis theory to validate machine learning models for science and engineering applications. Our results illustrate how principled numerical analysis methods can be coupled with existing ML training/testing methodologies to validate models for science and engineering applications.
arXiv Detail & Related papers (2022-02-17T07:56:46Z)
Heuristic machinery for thermodynamic studies of SU(N) fermions with neural networks [1.1910997817688513]
We introduce a machinery by using machine learning analysis. We use our machinery to guide the thermodynamic studies in the density profile of ultracold fermions interacting within SU($N$) spin symmetry. Our machine learning framework shows a potential to validate theoretical descriptions of SU($N$) Fermi liquids.
arXiv Detail & Related papers (2020-06-25T02:31:55Z)
Parsimonious neural networks learn interpretable physical laws [77.34726150561087]
We propose parsimonious neural networks (PNNs) that combine neural networks with evolutionary optimization to find models that balance accuracy with parsimony. The power and versatility of the approach is demonstrated by developing models for classical mechanics and to predict the melting temperature of materials from fundamental properties.
arXiv Detail & Related papers (2020-05-08T16:15:47Z)

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