241 research outputs found
How to erase surface plasmon fringes
We report the realization of a dual surface plasmon polariton (SPP)
microscope based on leakage radiation (LR) analysis. The microscope can either
image SPP propagation in the direct space or tin the Fourier space. This
particularity allows in turn manipulation of the LR image for a clear
separation of different interfering SPP contributions present close to optical
nanoelements.Comment: Appl. Phys. Lett. 89, 091117 (2006
An Efficient Large-Area Grating Coupler for Surface Plasmon Polaritons
We report the design, fabrication and characterization of a periodic grating
of shallow rectangular grooves in a metallic film with the goal of maximizing
the coupling efficiency of an extended plane wave (PW) of visible or
near-infrared light into a single surface plasmon polariton (SPP) mode on a
flat metal surface. A PW-to-SPP power conversion factor > 45 % is demonstrated
at a wavelength of 780 nm, which exceeds by an order of magnitude the
experimental performance of SPP grating couplers reported to date at any
wavelength. Conversion efficiency is maximized by matching the dissipative SPP
losses along the grating surface to the local coupling strength. This critical
coupling condition is experimentally achieved by tailoring the groove depth and
width using a focused ion beam.Comment: The final publication is available at http://www.springerlink.com.
http://dx.doi.org/10.1007/s11468-011-9303-
Transformation Optics for Plasmonics
A new strategy to control the flow of surface plasmon polaritons at metallic
surfaces is presented. It is based on the application of the concept of
Transformation Optics to devise the optical parameters of the dielectric medium
placed on top of the metal surface. We describe the general methodology for the
design of Transformation-Optical devices for surface plasmons and analyze, for
proof-of-principle purposes, three representative examples with different
functionalities: a beam shifter, a cylindrical cloak and a ground-plane cloak.Comment: 15 pages, 3 figure
Broadband and efficient plasmonic control in the near-infrared and visible via strong interference of surface plasmon polaritons
This paper was published in Optics Letters and is made available as an electronic reprint with the permission of OSA. The paper can be found at the following URL on the OSA website: http://dx.doi.org/10.1364/OL.38.004453 Systematic or multiple reproduction or distribution to multiple locations via electronic or other means is prohibited and is subject to penalties under law.Copyright © 2013 Optical Society of AmericaBroadband and tunable control of surface plasmon polaritons in the near-infrared and visible spectrum is demonstrated theoretically and numerically with a pair of phased nanoslits. We establish, with simulations supported by a coupled wave model, that by dividing the incident power equally between two input channels, the maximum plasmon intensity deliverable to either side of the nanoslit pair is twice that for an isolated slit. For a broadband source, a compact device with nanoslit separation of the order of a tenth of the wavelength is shown to steer nearly all the generated plasmons to one side for the same phase delay, thereby achieving a broadband unidirectional plasmon launcher. The reported effect can be applied to the design of ultra-broadband and efficient tunable plasmonic devices.Engineering and Physical Sciences Research Council (EPSRC
Integrated plasmonic circuitry on a vertical-cavity surface-emitting semiconductor laser platform
Integrated plasmonic sources and detectors are imperative in the practical development of plasmonic circuitry for bio- and chemical sensing, nanoscale optical information processing, as well as transducers for high-density optical data storage. Here we show that vertical-cavity surface-emitting lasers (VCSELs) can be employed as an on-chip, electrically pumped source or detector of plasmonic signals, when operated in forward or reverse bias, respectively. To this end, we experimentally demonstrate surface plasmon polariton excitation, waveguiding, frequency conversion and detection on a VCSEL-based plasmonic platform. The coupling efficiency of the VCSEL emission to waveguided surface plasmon polariton modes has been optimized using asymmetric plasmonic nanostructures. The plasmonic VCSEL platform validated here is a viable solution for practical realizations of plasmonic functionalities for various applications, such as those requiring sub-wavelength field confinement, refractive index sensitivity or optical near-field transduction with electrically driven sources, thus enabling the realization of on-chip optical communication and lab-on-a-chip devices
Plasmonic Luneburg and Eaton Lenses
Plasmonics is an interdisciplinary field focusing on the unique properties of
both localized and propagating surface plasmon polaritons (SPPs) -
quasiparticles in which photons are coupled to the quasi-free electrons of
metals. In particular, it allows for confining light in dimensions smaller than
the wavelength of photons in free space, and makes it possible to match the
different length scales associated with photonics and electronics in a single
nanoscale device. Broad applications of plasmonics have been realized including
biological sensing, sub-diffraction-limit imaging, focusing and lithography,
and nano optical circuitry. Plasmonics-based optical elements such as
waveguides, lenses, beam splitters and reflectors have been implemented by
structuring metal surfaces or placing dielectric structures on metals, aiming
to manipulate the two-dimensional surface plasmon waves. However, the abrupt
discontinuities in the material properties or geometries of these elements lead
to increased scattering of SPPs, which significantly reduces the efficiency of
these components. Transformation optics provides an unprecedented approach to
route light at will by spatially varying the optical properties of a material.
Here, motivated by this approach, we use grey-scale lithography to
adiabatically tailor the topology of a dielectric layer adjacent to a metal
surface to demonstrate a plasmonic Luneburg lens that can focus SPPs. We also
realize a plasmonic Eaton lens that can bend SPPs. Since the optical properties
are changed gradually rather than abruptly in these lenses, losses due to
scattering can be significantly reduced in comparison with previously reported
plasmonic elements.Comment: Accepted for publication in Nature Nanotechnolog
Efficient unidirectional nanoslit couplers for surface plasmons
Plasmonics is based on surface plasmon polariton (SPP) modes which can be
laterally confined below the diffraction limit, thereby enabling ultracompact
optical components. In order to exploit this potential, the fundamental
bottleneck of poor light-SPP coupling must be overcome. In established SPP
sources (using prism, grating} or nanodefect coupling) incident light is a
source of noise for the SPP, unless the illumination occurs away from the
region of interest, increasing the system size and weakening the SPP intensity.
Back-side illumination of subwavelength apertures in optically thick metal
films eliminates this problem but does not ensure a unique propagation
direction for the SPP. We propose a novel back-side slit-illumination method
based on drilling a periodic array of indentations at one side of the slit. We
demonstrate that the SPP running in the array direction can be suppressed, and
the one propagating in the opposite direction enhanced, providing localized
unidirectional SPP launching.Comment: 13 pages, 4 figure
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