Add to ORKGMachine learning approaches have the potential to approximate Density Functional Theory (DFT) for atomistic simulations in a computationally efficient manner, which could dramatically increase the impact of computational simulations on real-world problems. However, they are limited by their accuracy and the cost of generating labeled data. Here, we present an online active learning framework for accelerating the simulation of atomic systems efficiently and accurately by incorporating prior physical information learned by large-scale pre-trained graph neural network models from the Open Catalyst Project. Accelerating these simulations enables useful data to be generated more cheaply, allowing better models to be trained and more atomistic sy...
Machine learning encompasses tools and algorithms that are now becoming popular in almost all scient...
High-throughput screening of compounds for desirable electronic properties can allow for accelerated...
Machine learning (ML) methods are of rapidly growing interest for materials modeling, and yet, the u...
Electronic structure calculations, such as those employing Kohn–Sham density functional theory or ab...
Machine learning (ML) approximations to density functional theory (DFT) potential energy surfaces (P...
In materials science, the first principles modeling, especially density functional theory (DFT), ser...
Recent advances in quantum mechanical (QM)-based molecular dynamics (MD) simulations have used machi...
We demonstrate how a deep neural network (NN) trained on a data set of quantum mechanical (QM) DFT c...
Accurate modelling of chemical and physical interactions is crucial for obtaining thermodynamic and ...
Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles met...
The demonstrated success of transfer learning has popularized approaches that involve pretraining mo...
Molecular dynamics simulations are an important tool for describing the evolution of a chemical syst...
While the primary bottleneck to a number of computational workflows was not so long ago limited by p...
Being progressively applied in the design of highly active catalysts for energy devices, machine lea...
Understanding chemistry is essential for the optimization of reactions and the development of new re...
Machine learning encompasses tools and algorithms that are now becoming popular in almost all scient...
High-throughput screening of compounds for desirable electronic properties can allow for accelerated...
Machine learning (ML) methods are of rapidly growing interest for materials modeling, and yet, the u...
Electronic structure calculations, such as those employing Kohn–Sham density functional theory or ab...
Machine learning (ML) approximations to density functional theory (DFT) potential energy surfaces (P...
In materials science, the first principles modeling, especially density functional theory (DFT), ser...
Recent advances in quantum mechanical (QM)-based molecular dynamics (MD) simulations have used machi...
We demonstrate how a deep neural network (NN) trained on a data set of quantum mechanical (QM) DFT c...
Accurate modelling of chemical and physical interactions is crucial for obtaining thermodynamic and ...
Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles met...
The demonstrated success of transfer learning has popularized approaches that involve pretraining mo...
Molecular dynamics simulations are an important tool for describing the evolution of a chemical syst...
While the primary bottleneck to a number of computational workflows was not so long ago limited by p...
Being progressively applied in the design of highly active catalysts for energy devices, machine lea...
Understanding chemistry is essential for the optimization of reactions and the development of new re...
Machine learning encompasses tools and algorithms that are now becoming popular in almost all scient...
High-throughput screening of compounds for desirable electronic properties can allow for accelerated...
Machine learning (ML) methods are of rapidly growing interest for materials modeling, and yet, the u...