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Published December 5, 2011 | Published
Journal Article Open

Surface plasmon and photonic mode propagation in gold nanotubes with varying wall thickness

Abstract

Gold nanotube arrays are synthesized with a range of wall thicknesses (15 to >140 nm) and inner diameters of ∼200 nm using a hard-template method. A red spectral shift (>0.39 eV) with decreasing wall thickness is observed in dark-field spectra of nanotube arrays and single nanowire/nanotube heterostructures. Finite-difference-time-domain simulations show that nanotubes in this size regime support propagating surface plasmon modes as well as surface plasmon ring resonances at visible wavelengths (the latter is observed only for excitation directions normal to the nanotube long axis with transverse polarization). The energy of the surface plasmon modes decreases with decreasing wall thickness and is attributed to an increase in mode coupling between propagating modes in the nanotube core and outer surface and the circumference dependence of ring resonances. Surface plasmon mode propagation lengths for thicker-walled tubes increase by a factor of ∼2 at longer wavelengths (>700 nm), where ohmic losses in the metal are low, but thinner-walled tubes (30 nm) exhibit a more significant increase in surface plasmon propagation length (by a factor of more than four) at longer wavelengths. Additionally, nanotubes in this size regime support a photonic mode in their core, which does not change in energy with changing wall thickness. However, photonic mode propagation length is found to decrease for optically thin walls. Finally, correlations are made between the experimentally observed changes in dark-field spectra and the changes in surface plasmon mode properties observed in simulations for the various gold nanotube wall thicknesses and excitation conditions.

Additional Information

© 2011 American Physical Society. Received 9 September 2011; revised 14 November 2011; published 5 December 2011. The authors thank Harry Atwater for support and useful discussions. J.K. acknowledges support from The Nanotechnology for Clean energy NSF IGERT Program. D.M.O'C. acknowledges support from the 7th European Community Framework Program (ACTOSPED project; PIOF-GA-2008- 221230) and the Institute for Advanced Materials, Devices and Nanotechnology at Rutgers University. M.F. acknowledges support from the Caltech SURF Program.

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August 19, 2023
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