Linear scaling density matrix real time TDDFT: propagator unitarity and matrix truncation
Linear scaling density matrix real time TDDFT: propagator unitarity and matrix truncation
Real time, density matrix based, time dependent density functional theory (TDDFT) proceeds through the propagation of the density matrix, as opposed to the Kohn-Sham orbitals. It is possible to reduce the computational workload by imposing spatial cutoff radii on sparse matrices, and the propagation of the density matrix in this manner provides direct access to the optical response of very large systems, which would be otherwise impractical to obtain using the standard formulations of TDDFT. Following a brief summary of our implementation, along with several benchmark tests illustrating the validity of the method, we present an exploration of the factors affecting the accuracy of the approach. In particular, we investigate the effect of basis set size and matrix truncation, the key approximation used in achieving linear scaling, on the propagator unitarity and optical spectra. Finally, we illustrate that, with an appropriate density matrix truncation range applied, the computational load scales linearly with the system size and discuss the limitations of the approach.
O'rourke, Conn
2273b21c-9ba3-4ca4-952f-6676f3fe8bff
Bowler, David R.
db66fb34-efce-43ed-bfeb-74de308a682c
29 April 2015
O'rourke, Conn
2273b21c-9ba3-4ca4-952f-6676f3fe8bff
Bowler, David R.
db66fb34-efce-43ed-bfeb-74de308a682c
O'rourke, Conn and Bowler, David R.
(2015)
Linear scaling density matrix real time TDDFT: propagator unitarity and matrix truncation.
The Journal of Chemical Physics, 143.
(doi:10.1063/1.4919128).
Abstract
Real time, density matrix based, time dependent density functional theory (TDDFT) proceeds through the propagation of the density matrix, as opposed to the Kohn-Sham orbitals. It is possible to reduce the computational workload by imposing spatial cutoff radii on sparse matrices, and the propagation of the density matrix in this manner provides direct access to the optical response of very large systems, which would be otherwise impractical to obtain using the standard formulations of TDDFT. Following a brief summary of our implementation, along with several benchmark tests illustrating the validity of the method, we present an exploration of the factors affecting the accuracy of the approach. In particular, we investigate the effect of basis set size and matrix truncation, the key approximation used in achieving linear scaling, on the propagator unitarity and optical spectra. Finally, we illustrate that, with an appropriate density matrix truncation range applied, the computational load scales linearly with the system size and discuss the limitations of the approach.
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Accepted/In Press date: 19 January 2015
Published date: 29 April 2015
Identifiers
Local EPrints ID: 488531
URI: http://eprints.soton.ac.uk/id/eprint/488531
ISSN: 0021-9606
PURE UUID: 41e6c6f0-eaff-4d64-b313-0f6cc853ab81
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Date deposited: 26 Mar 2024 17:45
Last modified: 26 Mar 2024 17:45
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Author:
Conn O'rourke
Author:
David R. Bowler
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