Tunable long-distance light transportation along Au nanoparticle chains: promising for optical interconnect

Tunable light resonance transportation along a single long Au hemisphere nanoparticles (NPs) chain was studied. The realistic experimentally determined gold dielectric function was used for the simulation of Au localized surface plasmon polariton (LSPPs) effect. The resonance light energy with minimized attenuation and its bandwidth were quantitatively analyzed by inducing the effective mass which was observed to increase only with the length of Au NPs between the source and the test point. The geometric ratio g/r of NP size and gap were investigated at 5 µm far of NPs with different gaps from 0 to 70 nm. Strongest resonance can be achieved with g/r = 1.2 by the factor of 1.5 than the connected NPs. This resonance mode falls in the wavelength λ = 555 nm (green light), which is exactly the maximum sensitivity of a light-adapted eye of human beings.