An adaptive multiscale approach for electronic structure methods
An adaptive multiscale approach for electronic structure methods
Dokument öffnen (1.2MB)Datum der Veröffentlichung
2016Verlag / herausgebende Einrichtung
Institut für Numerische Simulation (INS)Verlagsort
BonnMetadaten
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Zitierbarer Link (Handle URI) 
https://hdl.handle.net/20.500.11811/11858
Inhalt
In this paper, we introduce a new scheme for the efficient numerical treatment of the electronic Schr¨odinger equation for molecules. It is based on the combination of a many-body expansion, which corresponds to the bond order dissection Anova approach introduced in [35, 42], with a hierarchy of basis sets of increasing order. Here, the energy is represented as a finite sum of contributions associated to subsets of nuclei and basis sets in a telescoping sum like fashion. Under the assumption of data locality of the electronic density (nearsightedness of electronic matter), the terms of this expansion decay rapidly and higher terms may be neglected. We further extend the approach in a dimension-adaptive fashion to generate quasi- optimal approximations, i.e. a specific truncation of the hierarchical series such that the total benefit is maximized for a fixed amount of costs. This way, we are able to achieve substantial speed up factors compared to conventional first principles methods depending on the molecular system under consideration. In particular, the method can deal efficiently with molecular systems which include only a small active part that needs to be described by accurate but expensive models.
Schlagwörter
multiscale method, electronic Schrödinger equation, sparse grid combination technique, many-body expansion, dimension-adaptive sparse grids
Klassifikation (DDC)
510 Mathematik 518 Numerische AnalysisErstpublikation
https://ins.uni-bonn.de/publication/preprintsZugehörige Publikation(en)
https://doi.org/10.1137/16M1088119Reihe, Nummer
INS Preprints ; 1601Griebel, Michael; Hamaekers, Jan; Chinnamsetty, Sambasiva Rao: An adaptive multiscale approach for electronic structure methods. In: INS Preprints, 1601.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11858
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/11858
@unpublished{handle:20.500.11811/11858,
author = {{Michael Griebel} and {Jan Hamaekers} and {Sambasiva Rao Chinnamsetty}},
title = {An adaptive multiscale approach for electronic structure methods},
publisher = {Institut für Numerische Simulation (INS)},
year = 2016,
INS Preprints},
volume = 1601,
note = {In this paper, we introduce a new scheme for the efficient numerical treatment of the electronic Schr¨odinger equation for molecules. It is based on the combination of a many-body expansion, which corresponds to the bond order dissection Anova approach introduced in [35, 42], with a hierarchy of basis sets of increasing order. Here, the energy is represented as a finite sum of contributions associated to subsets of nuclei and basis sets in a telescoping sum like fashion. Under the assumption of data locality of the electronic density (nearsightedness of electronic matter), the terms of this expansion decay rapidly and higher terms may be neglected. We further extend the approach in a dimension-adaptive fashion to generate quasi- optimal approximations, i.e. a specific truncation of the hierarchical series such that the total benefit is maximized for a fixed amount of costs. This way, we are able to achieve substantial speed up factors compared to conventional first principles methods depending on the molecular system under consideration. In particular, the method can deal efficiently with molecular systems which include only a small active part that needs to be described by accurate but expensive models.},
url = {https://hdl.handle.net/20.500.11811/11858}
}
author = {{Michael Griebel} and {Jan Hamaekers} and {Sambasiva Rao Chinnamsetty}},
title = {An adaptive multiscale approach for electronic structure methods},
publisher = {Institut für Numerische Simulation (INS)},
year = 2016,
INS Preprints},
volume = 1601,
note = {In this paper, we introduce a new scheme for the efficient numerical treatment of the electronic Schr¨odinger equation for molecules. It is based on the combination of a many-body expansion, which corresponds to the bond order dissection Anova approach introduced in [35, 42], with a hierarchy of basis sets of increasing order. Here, the energy is represented as a finite sum of contributions associated to subsets of nuclei and basis sets in a telescoping sum like fashion. Under the assumption of data locality of the electronic density (nearsightedness of electronic matter), the terms of this expansion decay rapidly and higher terms may be neglected. We further extend the approach in a dimension-adaptive fashion to generate quasi- optimal approximations, i.e. a specific truncation of the hierarchical series such that the total benefit is maximized for a fixed amount of costs. This way, we are able to achieve substantial speed up factors compared to conventional first principles methods depending on the molecular system under consideration. In particular, the method can deal efficiently with molecular systems which include only a small active part that needs to be described by accurate but expensive models.},
url = {https://hdl.handle.net/20.500.11811/11858}
}
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