Operation of Quantum Plasmonic Metasurfaces Using Electron Transport through Subnanometer Gaps

Takeuchi, Takashi; Noda, Minoru; Yabana, Kazuhiro

doi:10.1021/acsphotonics.9b00889

Cited by 18 publications

(15 citation statements)

References 49 publications

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“…At the locus of d ≤ 0 nm where the constituent spheres start to overlap geometrically, there is no potential barriers that prevent a conduction current from flowing throughout the metasurface. These trends had already been established in our previous study 44 .…”

Section: Resultssupporting

confidence: 83%

Extremely large third-order nonlinear optical effects caused by electron transport in quantum plasmonic metasurfaces with subnanometer gaps

Takeuchi

Yabana

2020

Sci Rep

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In this study, a third-order nonlinear optical responses in quantum plasmonic metasurfaces composed of metallic nano-objects with subnanometer gaps were investigated using time-dependent density functional theory, a fully quantum mechanical approach. At gap distances of ≥ 0.6 nm, the third-order nonlinearities monotonically increased as the gap distance decreased, owing to enhancement of the induced charge densities at the gaps between nano-objects. Particularly, when the third harmonic generation overlapped with the plasmon resonance, a large third-order nonlinearity was achieved. At smaller gap distances down to 0.1 nm, we observed the appearance of extremely large third-order nonlinearity without the assistance of the plasmon resonance. At a gap distance of 0.1 nm, the observed third-order nonlinearity was approximately three orders of magnitude larger than that seen at longer gap distances. The extremely large third-order nonlinearities were found to originate from electron transport by quantum tunneling and/or overbarrier currents through the subnanometer gaps.

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Section: Resultssupporting

confidence: 83%

Extremely large third-order nonlinear optical effects caused by electron transport in quantum plasmonic metasurfaces with subnanometer gaps

Takeuchi

Yabana

2020

Sci Rep

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“…Moreover, the example explicitly demonstrates that the KS current density differs from the true current density by a rotational component. Although this has been recognized before to be theoretically possible [35,[40][41][42][43], not only is this difference neglected in applications today where typically the current calculated from the KS orbitals is assumed to represent the true current [44,45], but the difference has not been demonstrated for systems beyond the linear response regime.…”

Section: Introductionmentioning

confidence: 99%

Exact time-dependent density-functional theory for nonperturbative dynamics of the helium atom

et al. 2021

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By inverting the time-dependent Kohn-Sham equation for a numerically exact dynamics of the helium atom, we show that the dynamical step and peak features of the exact correlation potential found previously in onedimensional models persist for real three-dimensional systems. We demonstrate that the Kohn-Sham and true current densities differ by a rotational component. The results have direct implications for approximate timedependent density functional theory calculations of atoms and molecules in strong fields, emphasizing the need to go beyond the adiabatic approximation, and highlighting caution in the quantitative use of the Kohn-Sham current.

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“…On the other hand, a meso- or macroscopic system is treated by continuum models on a spatial grid expression, abandoning the atomistic description. Electromagnetic analyses are then carried out by solving the Maxwell equation numerically or analytically with dielectric functions or polarizability on the grid cells. ,− Some intermediate types of methods such as electron dynamics in the hydrodynamic expression and the Jellium approximation which use simpler quantum Hamiltonian models, − and a hybrid approach of the continuum model with first-principles calculation have recently been developed, − which have allowed one to analyze the optical response of electrons in a mesoscopic system.…”

Section: Introductionmentioning

confidence: 99%

Computational Analyses of Plasmonics of a Silver Nanoparticle in a Vacuum and in a Water Solution by Classical Electronic and Molecular Dynamics Simulations

Yamada

2022

J. Phys. Chem. A

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We present basic optical responses of a silver nanoparticle (Ag 309 ) in a vacuum and a water solution obtained by classical electronic and molecular dynamics (CEMD) calculations, where the CEMD is our previously developed force-field based molecular dynamics simulation method that incorporates the classical equation of motion for free electrons in metal and an interaction with the applied oscillating electric field (Yamada, A. J. Chem. Phys. 2021, 155, 174118)). The present work is the follow-up of the previous study. Calculated absorption spectra in the visible region with various conditions are reported together with parameter determination for realistic analyses as well as the verification of the method. Time-domain optical responses of Ag 309 in water solvent are as well analyzed in terms of the plasmon resonance excitation under a subpicosecond light pulse and its thermal relaxation.

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Operation of Quantum Plasmonic Metasurfaces Using Electron Transport through Subnanometer Gaps

Cited by 18 publications

References 49 publications

Extremely large third-order nonlinear optical effects caused by electron transport in quantum plasmonic metasurfaces with subnanometer gaps

Extremely large third-order nonlinear optical effects caused by electron transport in quantum plasmonic metasurfaces with subnanometer gaps

Exact time-dependent density-functional theory for nonperturbative dynamics of the helium atom

Computational Analyses of Plasmonics of a Silver Nanoparticle in a Vacuum and in a Water Solution by Classical Electronic and Molecular Dynamics Simulations

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