Howard R. Stuart scite author profile

We report the effect of metal-island size variation in nanoparticle-enhanced photodetectors. Nanoparticle size was controlled by varying the deposition and annealing conditions used to produce the metal-island films. Increasing the size of silver-island particles fabricated onto 165 nm thick silicon-on-insulator (SOI) photodetectors resulted in a dramatic increase in the observed photocurrent. A nearly factor-of-20 photocurrent enhancement was observed for light of wavelength 800 nm, a significant improvement over previously reported results. The improvement is linked to two physical effects: the increased scattering efficiency of the larger nanoparticles and a qualitative change in the resonance characteristics of the metal-island film due to radiative coupling to the SOI waveguide modes.

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Absorption enhancement in silicon-on-insulator waveguides using metal island films

Stuart¹,

Hall²

1996

327

209

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We report the degree to which the resonances associated with metal island films can be used to enhance the sensitivity of very thin semiconductor photodetectors. The island films can couple incident light into the waveguide modes of the detector, resulting in increased absorption. To characterize the coupling, silver-, gold-, and copper-island layers were formed on the surface of a thin-film photodetector fabricated in the 0.16 μm thick silicon layer of a silicon-on-insulator (SOI) wafer. The copper islands gave the best result, producing more than an order of magnitude enhancement in the photocurrent for light of wavelength 800 nm. The enhancements appear to be due primarily to coupling between the metal island resonances and the waveguide modes supported by the SOI structure.

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Enhanced Dipole-Dipole Interaction between Elementary Radiators Near a Surface

1998

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We report the results of elastic light-scattering measurements of random silver nanoparticle arrays fabricated onto structures supporting optical surface modes (i.e., surface plasmons or waveguide modes). We observe dramatic, qualitative changes in the resonance structure of the nanoparticle layer due to coupling with the propagating modes. The effect appears to arise because the underlying surface modes mediate an enhanced dipole-dipole interaction between individual nanoparticles. A calculation that supports this interpretation is described. [S0031-9007(98)06415-1]

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Lower Bounds on the Q of Electrically Small Dipole Antennas

Yaghjian

Stuart²

2010

IEEE Trans. Antennas Propagat.

103

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Thermodynamic limit to light trapping in thin planar structures

1997

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Howard R. Stuart

Island size effects in nanoparticle-enhanced photodetectors

Absorption enhancement in silicon-on-insulator waveguides using metal island films

Enhanced Dipole-Dipole Interaction between Elementary Radiators Near a Surface

Lower Bounds on the Q of Electrically Small Dipole Antennas

Thermodynamic limit to light trapping in thin planar structures

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