The two main thrusts of computational science are increasingly accurate predictions and faster calculations; to this end, the zeitgeist in molecular dynamics (MD) simulations is pursuing machine learned and data driven interatomic models, e.g. neural network potentials, and novel hardware architectures, e.g. GPUs. Current implementations of neural network potentials are orders of magnitude slower than traditional interatomic models and while looming exascale computing offers the ability to run large, accurate simulations with these models, achieving portable performance for MD with new and varied exascale hardware requires rethinking traditional algorithms, using novel data structures, and library solutions. We re-implement a neural network...
Detailed brain modeling has been presenting significant challenges to the world of high-performance ...
Atomistic Molecular Dynamics (MD) simulations provide researchers the ability to model biomolecular ...
Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles met...
Molecular dynamics (MD) is a powerful computer simulation technique providing atomistic resolution a...
Despite the impending flattening of Moore's law, the system size, complexity, and length of molecula...
Parametric and non-parametric machine learning potentials have emerged recently as a way to improve ...
We present the GPU version of DeePMD-kit, which, upon training a deep neural network model using ab ...
The molecular dynamics (MD) simulation is a favored method in materials science for understanding an...
Abstract—Special-purpose computing hardware can provide significantly better performance and power e...
We implement a method for constructing analytic interatomic potentials by fitting artificial neural ...
Molecular mechanics and dynamics are becoming widely used to perform simulations of molecular system...
We report the design and performance of a computational molecular dynamics (MD) code for 400 million...
We develop a neuroevolution-potential (NEP) framework for generating neural network-based machine-le...
A 100-million-atom biomolecular simulation with NAMD is one of the three benchmarks for the NSF-fund...
Recent advances in quantum mechanical (QM)-based molecular dynamics (MD) simulations have used machi...
Detailed brain modeling has been presenting significant challenges to the world of high-performance ...
Atomistic Molecular Dynamics (MD) simulations provide researchers the ability to model biomolecular ...
Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles met...
Molecular dynamics (MD) is a powerful computer simulation technique providing atomistic resolution a...
Despite the impending flattening of Moore's law, the system size, complexity, and length of molecula...
Parametric and non-parametric machine learning potentials have emerged recently as a way to improve ...
We present the GPU version of DeePMD-kit, which, upon training a deep neural network model using ab ...
The molecular dynamics (MD) simulation is a favored method in materials science for understanding an...
Abstract—Special-purpose computing hardware can provide significantly better performance and power e...
We implement a method for constructing analytic interatomic potentials by fitting artificial neural ...
Molecular mechanics and dynamics are becoming widely used to perform simulations of molecular system...
We report the design and performance of a computational molecular dynamics (MD) code for 400 million...
We develop a neuroevolution-potential (NEP) framework for generating neural network-based machine-le...
A 100-million-atom biomolecular simulation with NAMD is one of the three benchmarks for the NSF-fund...
Recent advances in quantum mechanical (QM)-based molecular dynamics (MD) simulations have used machi...
Detailed brain modeling has been presenting significant challenges to the world of high-performance ...
Atomistic Molecular Dynamics (MD) simulations provide researchers the ability to model biomolecular ...
Machine-learning potentials (MLPs) trained on data from quantum-mechanics based first-principles met...