2010
DOI: 10.1088/1367-2630/12/8/083062
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The effects of retardation on plasmon hybridization within metallic nanostructures

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Cited by 35 publications
(24 citation statements)
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“…For a single metal shell, the cavity plasmon and the surface plasmon hybridize to form symmetric and anti-symmetric plasmons of which frequencies are significantly different. Similar hybridization has been studied in metal nanotubes 22,23 and coupled metal nanowires 24 . Plasmon hybridization in the nanowires structures can be succinctly described in a manner similar to molecular orbital hybridization, as shown in Figure 1a Inset 18,19,20 .…”
Section: Resultsmentioning
confidence: 64%
“…For a single metal shell, the cavity plasmon and the surface plasmon hybridize to form symmetric and anti-symmetric plasmons of which frequencies are significantly different. Similar hybridization has been studied in metal nanotubes 22,23 and coupled metal nanowires 24 . Plasmon hybridization in the nanowires structures can be succinctly described in a manner similar to molecular orbital hybridization, as shown in Figure 1a Inset 18,19,20 .…”
Section: Resultsmentioning
confidence: 64%
“…formulas (9) and (10), E (0) k (Q) and a k (Q) are computed. Finally, using formula (8), ε (2) k is calculated.…”
Section: B Radiation Correctionsmentioning
confidence: 99%
“…As the dimensions of nanoparticle are increased, the quasistatic condition is not strictly valid, and retardation (wave) effects manifest themselves. [7][8][9][10] In this situation, the accuracy of the electrostatic approximation may be compromised and appropriate radiation corrections for the calculation of resonance permittivities are needed. By using the perturbation technique, such radiation corrections have been derived.…”
Section: Introductionmentioning
confidence: 99%
“…For other shapes, however, analytical solutions are not available [72] and they must be studied numerically or via plasmon hybridization theory. The advent of plasmon hybridisation theory [75] in 2003 has made it easier to analytically describe plasmon modes in a range of exotic nanostructures, from nanoshells [75], to nanorice [76], to nanotubes with dielectric cores [77]. This is done by describing the interaction of plasmon modes supported by basic structures.…”
Section: Physical Foundations For Surface Plasmonsmentioning
confidence: 99%
“…This is done by describing the interaction of plasmon modes supported by basic structures. For example, plasmon modes of nanoshells could be described as two fundamental dipolar modes [11], with one mode supported on the outside of a larger outer nanosphere and one mode on the surface of a smaller inner dielectric nanosphere or 'void' [77]. Some further important relations, i.e., dispersion equations and resonant frequencies of SPPs and LSPs are listed in Table 1 and discussed in greater detail in Section 3.3.…”
Section: Physical Foundations For Surface Plasmonsmentioning
confidence: 99%