We present ONETEP (order-N electronic total energy package), a density functional program for parallel computers whose computational cost scales linearly with the number of atoms and the number of processors. ONETEP is based on our reformulation of the plane wave pseudopotential method which exploits the electronic localization that is inherent in systems with a nonvanishing band gap. We summarize the theoretical developments that enable the direct optimization of strictly localized quantities expressed in terms of a delocalized plane wave basis. These same localized quantities lead us to a physical way of dividing the computational effort among many processors to allow calculations to be performed efficiently on parallel supercomputers. We...
While density functional theory (DFT) allows accurate quantum mechanical simulations from first prin...
Simulations of materials from first principles have improved drastically over the last few decades, ...
Abstract: Many systems of great importance in material science, chemistry, solid-state physics, and ...
ONETEP is an ab initio electronic structure package for total energy calculations within density-fun...
ONETEP is an ab initio electronic structure package for total energy calculations within density-fun...
We describe the algorithms we have developed for linear-scaling plane wave density functional calcul...
We present an overview of the onetep program for linear-scaling density functional theory (DFT) calc...
This paper provides a general overview of the methodology implemented in onetep (Order-N Electronic ...
We present a detailed comparison between ONETEP, our linear-scaling density functional method, and t...
Quantum mechanical simulation of realistic models of nanostructured systems, such as nanocrystals an...
An overview of the ONETEP (Order-N Electronic Total Energy Package) code is presented, focusing on t...
We present an approach for computing Landauer–Büttiker ballistic electronic transport for multi-lead...
We extend our linear-scaling approach for the calculation of Hartree–Fock exchange energy using loca...
Linear-scaling methods for density functional theory promise to revolutionize the scope and scale of...
ONETEP is a linear scaling code for performing first-principles total energy calculations within den...
While density functional theory (DFT) allows accurate quantum mechanical simulations from first prin...
Simulations of materials from first principles have improved drastically over the last few decades, ...
Abstract: Many systems of great importance in material science, chemistry, solid-state physics, and ...
ONETEP is an ab initio electronic structure package for total energy calculations within density-fun...
ONETEP is an ab initio electronic structure package for total energy calculations within density-fun...
We describe the algorithms we have developed for linear-scaling plane wave density functional calcul...
We present an overview of the onetep program for linear-scaling density functional theory (DFT) calc...
This paper provides a general overview of the methodology implemented in onetep (Order-N Electronic ...
We present a detailed comparison between ONETEP, our linear-scaling density functional method, and t...
Quantum mechanical simulation of realistic models of nanostructured systems, such as nanocrystals an...
An overview of the ONETEP (Order-N Electronic Total Energy Package) code is presented, focusing on t...
We present an approach for computing Landauer–Büttiker ballistic electronic transport for multi-lead...
We extend our linear-scaling approach for the calculation of Hartree–Fock exchange energy using loca...
Linear-scaling methods for density functional theory promise to revolutionize the scope and scale of...
ONETEP is a linear scaling code for performing first-principles total energy calculations within den...
While density functional theory (DFT) allows accurate quantum mechanical simulations from first prin...
Simulations of materials from first principles have improved drastically over the last few decades, ...
Abstract: Many systems of great importance in material science, chemistry, solid-state physics, and ...