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RESEARCH PRODUCT
Kohn-Sham Decomposition in Real-Time Time-Dependent Density-Functional Theory An Efficient Tool for Analyzing Plasmonic Excitations
Paul ErhartTuomas P. RossiMikael KuismaMikael KuismaRisto M. NieminenMartti J. Puskasubject
plasmonic excitationsTheoretical computer scienceKohn-Sham decompositionComputer scienceta221Kohn–Sham equationsFOS: Physical sciencesPhysics::Optics02 engineering and technology01 natural sciencesPhysics - Chemical Physics0103 physical sciencesMesoscale and Nanoscale Physics (cond-mat.mes-hall)Decomposition (computer science)Physics::Atomic and Molecular ClustersStatistical physicsPhysical and Theoretical ChemistryPhysics::Chemical Physics010306 general physicsta116PlasmonEigenvalues and eigenvectorsChemical Physics (physics.chem-ph)Condensed Matter - Materials ScienceCondensed Matter - Mesoscale and Nanoscale Physicsta114tiheysfunktionaaliteoriaMaterials Science (cond-mat.mtrl-sci)Time-dependent density functional theory16. Peace & justice021001 nanoscience & nanotechnologyComputer Science ApplicationsplasmonitBenzene derivativesnanohiukkaset0210 nano-technologydescription
The real-time-propagation formulation of time-dependent density-functional theory (RT-TDDFT) is an efficient method for modeling the optical response of molecules and nanoparticles. Compared to the widely adopted linear-response TDDFT approaches based on, e.g., the Casida equations, RT-TDDFT appears, however, lacking efficient analysis methods. This applies in particular to a decomposition of the response in the basis of the underlying single-electron states. In this work, we overcome this limitation by developing an analysis method for obtaining the Kohn-Sham electron-hole decomposition in RT-TDDFT. We demonstrate the equivalence between the developed method and the Casida approach by a benchmark on small benzene derivatives. Then, we use the method for analyzing the plasmonic response of icosahedral silver nanoparticles up to Ag$_{561}$. Based on the analysis, we conclude that in small nanoparticles individual single-electron transitions can split the plasmon into multiple resonances due to strong single-electron-plasmon coupling whereas in larger nanoparticles a distinct plasmon resonance is formed.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-03-08 | JOURNAL OF CHEMICAL THEORY AND COMPUTATION |