Selective Excitation of Plasmon Resonances of Single Au Triangles by Polarization-Dependent Light Excitation

Awada, Chawki; Popescu, Traian; Douillard, Ludovic; Charra, Fabrice; Perron, Antoine; Yockell-Lelièvre, Hélène; Baudrion, Anne-Laure; Adam, Pierre‐Michel; Bachelot, Renaud

doi:10.1021/jp303475c

Cited by 71 publications

(77 citation statements)

References 72 publications

(106 reference statements)

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“…Resonances at = 750 nm and = 800 nm corresponds to the dipolar contributions; the intensity maps in Figs. 1(d) and 1(e) shows that the normalized electric field resonances are located close to the corners, in agreement with previous work [13]. The logarithms of the magnitude of the electric field enhancement at the dipolar resonance (1.3 for x-polarized and 1.6 for y-polarized) are larger than those obtained for the quadrupolar resonance (0.8 for xpolarized and 0.9 for y-polarized).…”

Section: Resultssupporting

confidence: 91%

On the absorption and electromagnetic field spectral shifts in plasmonic nanotriangle arrays

et al. 2014

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The behavior of the electromagnetic field interaction with gold nanotriangles organized in bow-tie arrays is investigated. A side-by-side comparison between the measured absorbance of the array and the modelled integrated electric field resonances confined around the gold structures is presented and discussed to explain the spectral shift between both parameters. Finite difference time domain calculations and Raman measurements of gold triangles of different sizes and periodicity are systematically performed. Numerical calculations show that the spectral maximum of the electric field varies in distinct areas over the metallic structures.

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Section: Resultssupporting

confidence: 91%

On the absorption and electromagnetic field spectral shifts in plasmonic nanotriangle arrays

et al. 2014

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“…A one-to-one correspondence is evident and whenever the spectrum in Figure 1 suggests a pair of degenerate states, the corresponding modes in Figure 2 support that they are indeed pairs of orthogonal and degenerate states. The energy degeneracies exhibited here are a direct consequence of the symmetries of the considered nanostructure, as required by group theory57.…”

Section: Resultsmentioning

confidence: 77%

Plasmonic eigenmodes in individual and bow-tie graphene nanotriangles

Wang

Christensen

Jauho

et al. 2015

Sci Rep

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In classical electrodynamics, nanostructured graphene is commonly modeled by the computationally demanding problem of a three-dimensional conducting film of atomic-scale thickness. Here, we propose an efficient alternative two-dimensional electrostatic approach where all calculation procedures are restricted to the graphene sheet. Furthermore, to explore possible quantum effects, we perform tight-binding calculations, adopting a random-phase approximation. We investigate multiple plasmon modes in 20 nm equilateral triangles of graphene, treating the optical response classically as well as quantum mechanically. Compared to the classical plasmonic spectrum which is “blind” to the edge termination, we find that the quantum plasmon frequencies exhibit blueshifts in the case of armchair edge termination of the underlying atomic lattice, while redshifts are found for zigzag edges. Furthermore, we find spectral features in the zigzag case which are associated with electronic edge states not present for armchair termination. Merging pairs of triangles into dimers, plasmon hybridization leads to energy splitting that appears strongest in classical calculations while splitting is lower for armchair edges and even more reduced for zigzag edges. Our various results illustrate a surprising phenomenon: Even 20 nm large graphene structures clearly exhibit quantum plasmonic features due to atomic-scale details in the edge termination.

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“…It is these electric near-field distributions that will be used in one of the approaches proposed below to predict the intensity and angular distribution of the emitted light as a function of the tip excitation position on the NP. Due to the small NP size, we may restrict ourselves to the dipolar resonances since higher-order multipole resonances [42][43][44] are comparatively much less pronounced, and occur above 2.4 eV according to our calculations.…”

Section: Resultsmentioning

confidence: 99%

“…2(e)]. The nanotriangle supports four basic dipolar excitations: a vertical dipole perpendicular to the substrate, and three degenerate in-plane dipolar modes [42,43], which can be expressed as p x =ê x p || , and…”

Section: Resultsmentioning

confidence: 99%

Engineering the emission of light from a scanning tunneling microscope using the plasmonic modes of a nanoparticle

et al. 2016

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The inelastic tunnel current in the junction formed between the tip of a scanning tunneling microscope (STM) and the sample can electrically generate optical signals. This phenomenon is potentially of great importance for nano-optoelectronic devices. In practice, however, the properties of the emitted light are difficult to control because of the strong influence of the STM tip. In this work, we show both theoretically and experimentally that the sought-after, well-controlled emission of light from an STM tunnel junction may be achieved using a nonplasmonic STM tip and a plasmonic nanoparticle on a transparent substrate. We demonstrate that the native plasmon modes of the nanoparticle may be used to engineer the light emitted in the substrate. Both the angular distribution and intensity of the emitted light may be varied in a predictable way by choosing the excitation position of the STM tip on the particle.

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Selective Excitation of Plasmon Resonances of Single Au Triangles by Polarization-Dependent Light Excitation

Cited by 71 publications

References 72 publications

On the absorption and electromagnetic field spectral shifts in plasmonic nanotriangle arrays

On the absorption and electromagnetic field spectral shifts in plasmonic nanotriangle arrays

Plasmonic eigenmodes in individual and bow-tie graphene nanotriangles

Engineering the emission of light from a scanning tunneling microscope using the plasmonic modes of a nanoparticle

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