4 May 2011 Design of cascaded plasmon resonances for ultrafast nonlinear optical switching
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Abstract
The optical properties of cascaded plasmon resonant metallic nanocomposites are investigated. Plasmon resonances and their related field distributions are numerically evaluated in two-dimensional arrays of spherical silver nanoparticles embedded in a dielectric host. The field distributions in structures with identical particle sizes indicate the presence of a largely dipolar particle response, with a small multipole resonance contribution at high frequency. However, in arrays consisting of particles with dissimilar sizes, an additional coupled mode appears in which the dipole moment in adjacent particles is found to be anti-parallel. For increasing size-dissimilarity a higher electric field enhancement is observed inside the small metal nanospheres, indicative of a cascaded field enhancement effect. This effect may be used to enhance the nonlinear optical response of an effective medium composed of particles with engineered size dispersion and particle placement.
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S. Toroghi, P. G. Kik, "Design of cascaded plasmon resonances for ultrafast nonlinear optical switching", Proc. SPIE 8054, Enabling Photonics Technologies for Defense, Security, and Aerospace Applications VII, 80540E (4 May 2011); doi: 10.1117/12.884045; http://dx.doi.org/10.1117/12.884045
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KEYWORDS
Particles

Nanoparticles

Plasmons

Absorption

Dielectrics

Silver

Nanocomposites

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