Optical properties and interparticle coupling of plasmonic bowtie nanoantennas on a semiconducting substrate

Optical properties and interparticle coupling of plasmonic bowtie nanoantennas on a semiconducting substrate

We present the simulation, fabrication, and optical characterization of plasmonic gold bowtie nanoantennas on a semiconducting GaAs substrate as geometrical parameters such as size, feed gap, height, and polarization of the incident light are varied. The surface-plasmon resonance was probed using wh...

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Bibliographic Details
Published in:Physical review. B, Condensed matter and materials physics Vol. 90; no. 3
Main Authors: Schraml, K., Spiegl, M., Kammerlocher, M., Bracher, G., Bartl, J., Campbell, T., Finley, J. J., Kaniber, M.
Format: Journal Article
Language:English
Published: 23-07-2014
Subjects:
Antennas
Gallium arsenide
Gallium arsenides
Glass
Gold
Nanostructure
Plasmonics
Simulation
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Summary:We present the simulation, fabrication, and optical characterization of plasmonic gold bowtie nanoantennas on a semiconducting GaAs substrate as geometrical parameters such as size, feed gap, height, and polarization of the incident light are varied. The surface-plasmon resonance was probed using white light reflectivity on an array of nominally identical, 35-nm-thick gold antennas. To elucidate the influence of the semiconducting, high-refractive-index substrate, all experiments were compared using nominally identical structures on glass. Besides a linear shift of the surface-plasmon resonance from 1.08 to 1.58 eV when decreasing the triangle size from 170 to 100 nm on GaAs, we observed a global redshift by 0.25 + or - 0.05 eV with respect to nominally identical structures on glass. By performing polarization-resolved measurements and comparing results with finite-difference time-domain simulations, we determined the near-field coupling between the two triangles composing the bowtie antenna to be ~ 8 times stronger when the antenna is on a glass substrate compared to when it is on a GaAs substrate. The results obtained have strong relevance for the integration of lithographically defined plasmonic nanoantennas on semiconducting substrates and therefore for the development of novel optically active plasmonic-semiconducting nanostructures.
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ISSN:1098-0121
1550-235X
DOI:10.1103/PhysRevB.90.035435