Nonadiabatic molecular dynamics (NAMD) simulations of molecular systems require the efficient evaluation of excited-state properties, such as energies, gradients, and nonadiabatic coupling vectors. Here, we investigate the use of graphics processing units (GPUs) in addition to central processing units (CPUs) to efficiently calculate these properties at the time-dependent density functional theory (TDDFT) level of theory. Our implementation in the FermiONs++ program package uses the J-engine and a preselective screening procedure for the calculation of Coulomb and exchange kernels, respectively. We observe good speed-ups for small and large molecular systems (comparable to those observed in ground-state calculations) and reduced (down to sub...
The Born‐Oppenheimer approximation constitutes a cornerstone of our understanding of molecules and t...
Department of ChemistryTheoretical and computational approaches are employed to study excited conden...
International audienceNonadiabatic dynamics simulations in the long timescale (much longer than 10 p...
Nonadiabatic molecular dynamics (NAMD) simulations of molecular systems require the efficient evalua...
Starting from our recently published implementation of nonadiabatic molecular dynamics (NAMD) on gra...
Abstract: Molecular mechanics simulations offer a computational approach to study the behavior of bi...
Reactive molecular dynamics (MD) simulation is a powerful research tool for describing chemical reac...
Direct atomistic simulation of nonadiabatic molecular dynamics is a challenging goal that allows imp...
We present a versatile new code released for open community use, the nonadiabatic excited state mole...
CONSPECTUS: Recent developments in nonadiabatic dynamics enabled ab inito simulations of complex ult...
In several fields of research, molecular dynamics simulation techniques are exploited to evaluate th...
We present an efficient approach for surface hopping-based nonadiabatic dynamics in the condensed ph...
Over the past decades, an important number of methods have been developed to simulate the nonadiabat...
Gaussian wavepacket methods have been widely employed for the investigation of nonadiabatic molecula...
Atomistic Molecular Dynamics (MD) simulations provide researchers the ability to model biomolecular ...
The Born‐Oppenheimer approximation constitutes a cornerstone of our understanding of molecules and t...
Department of ChemistryTheoretical and computational approaches are employed to study excited conden...
International audienceNonadiabatic dynamics simulations in the long timescale (much longer than 10 p...
Nonadiabatic molecular dynamics (NAMD) simulations of molecular systems require the efficient evalua...
Starting from our recently published implementation of nonadiabatic molecular dynamics (NAMD) on gra...
Abstract: Molecular mechanics simulations offer a computational approach to study the behavior of bi...
Reactive molecular dynamics (MD) simulation is a powerful research tool for describing chemical reac...
Direct atomistic simulation of nonadiabatic molecular dynamics is a challenging goal that allows imp...
We present a versatile new code released for open community use, the nonadiabatic excited state mole...
CONSPECTUS: Recent developments in nonadiabatic dynamics enabled ab inito simulations of complex ult...
In several fields of research, molecular dynamics simulation techniques are exploited to evaluate th...
We present an efficient approach for surface hopping-based nonadiabatic dynamics in the condensed ph...
Over the past decades, an important number of methods have been developed to simulate the nonadiabat...
Gaussian wavepacket methods have been widely employed for the investigation of nonadiabatic molecula...
Atomistic Molecular Dynamics (MD) simulations provide researchers the ability to model biomolecular ...
The Born‐Oppenheimer approximation constitutes a cornerstone of our understanding of molecules and t...
Department of ChemistryTheoretical and computational approaches are employed to study excited conden...
International audienceNonadiabatic dynamics simulations in the long timescale (much longer than 10 p...