We push the boundaries of electronic structure-based \textit{ab-initio} molecular dynamics (AIMD) beyond 100 million atoms. This scale is otherwise barely reachable with classical force-field methods or novel neural network and machine learning potentials. We achieve this breakthrough by combining innovations in linear-scaling AIMD, efficient and approximate sparse linear algebra, low and mixed-precision floating-point computation on GPUs, and a compensation scheme for the errors introduced by numerical approximations. The core of our work is the non-orthogonalized local submatrix method (NOLSM), which scales very favorably to massively parallel computing systems and translates large sparse matrix operations into highly parallel, dense matr...
International audienceWe present a way to improve the performance of the electronic structure Vienna...
We present a new linear scaling ab initio total energy electronic structure calculation method based...
The two main thrusts of computational science are increasingly accurate predictions and faster calcu...
We push the boundaries of electronic structure-based ab-initio molecular dynamics (AIMD) beyond 100 ...
The non-orthogonal local submatrix method applied to electronic-structure based molecular dynamics s...
We present the GPU version of DeePMD-kit, which, upon training a deep neural network model using ab ...
Abstract: Many systems of great importance in material science, chemistry, solid-state physics, and ...
Development of new materials needs better understanding of the behavior of materials at nanoscale wh...
Molecular dynamics (MD) simulations employing classical force fields constitute the cornerstone of c...
Abstract: Molecular mechanics simulations offer a computational approach to study the behavior of bi...
Owing to the computational complexity of electronic structure algorithms running on classical digita...
We describe a complete set of algorithms for ab initio molecular simulations based on numerically ta...
The recent progress of linear-scaling or O(<i>N</i>) methods in density functional theory (DFT) is ...
Even when using parametrized semiempirical methods, quantum chemical calculations on molecules conta...
Machine learning approaches have the potential to approximate Density Functional Theory (DFT) for at...
International audienceWe present a way to improve the performance of the electronic structure Vienna...
We present a new linear scaling ab initio total energy electronic structure calculation method based...
The two main thrusts of computational science are increasingly accurate predictions and faster calcu...
We push the boundaries of electronic structure-based ab-initio molecular dynamics (AIMD) beyond 100 ...
The non-orthogonal local submatrix method applied to electronic-structure based molecular dynamics s...
We present the GPU version of DeePMD-kit, which, upon training a deep neural network model using ab ...
Abstract: Many systems of great importance in material science, chemistry, solid-state physics, and ...
Development of new materials needs better understanding of the behavior of materials at nanoscale wh...
Molecular dynamics (MD) simulations employing classical force fields constitute the cornerstone of c...
Abstract: Molecular mechanics simulations offer a computational approach to study the behavior of bi...
Owing to the computational complexity of electronic structure algorithms running on classical digita...
We describe a complete set of algorithms for ab initio molecular simulations based on numerically ta...
The recent progress of linear-scaling or O(<i>N</i>) methods in density functional theory (DFT) is ...
Even when using parametrized semiempirical methods, quantum chemical calculations on molecules conta...
Machine learning approaches have the potential to approximate Density Functional Theory (DFT) for at...
International audienceWe present a way to improve the performance of the electronic structure Vienna...
We present a new linear scaling ab initio total energy electronic structure calculation method based...
The two main thrusts of computational science are increasingly accurate predictions and faster calcu...