Investigating the influences of the precise manufactured shape of dipole nanoantennas on their optical properties

Moosmann, Carola; Sigurdsson, G.; Wissert, Matthias D.; Dopf, Katja; Lemmer, Uli; Eisler, Hans‐Jürgen

doi:10.1364/oe.21.000594

Cited by 7 publications

(6 citation statements)

References 24 publications

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“…We neither included the surface roughness, nor the exact realistic geometry, which is known to change the optical response and which can be deduced from scanning electron microscopy images and atomic force microscopy data [27], nor additional effects due to grain boundaries. Furthermore, we assumed a homogeneous oxidation and therefore a smooth oxide layer with constant thickness.…”

Section: Simulationsmentioning

confidence: 99%

Oxide mediated spectral shifting in aluminum resonant optical antennas

Schwab¹,

Moosmann²,

Dopf³

et al. 2015

Opt. Express

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Abstract:As a key feature among metals showing good plasmonic behavior, aluminum extends the spectrum of achievable plasmon resonances of optical antennas into the deep ultraviolet. Due to degradation, a native oxide layer gives rise to a metal-core/oxide-shell nanoparticle and influences the spectral resonance peak position. In this work, we examine the role of the underlying processes by applying numerical nanoantenna models that are experimentally not feasible. Finite-difference time-domain simulations are carried out for a large variety of elongated single-arm and two-arm gap nanoantennas. In a detailed analysis, which takes into account the varying surface-to-volume ratio, we show that the overall spectral shift toward longer wavelengths is mainly driven by the higher index surrounding material rather than by the decrease of the initial aluminum volume. In addition, we demonstrate experimentally that this shifting can be minimized by an all-inert fabrication and subsequent proof-of-concept encapsulation.

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Section: Simulationsmentioning

confidence: 99%

Oxide mediated spectral shifting in aluminum resonant optical antennas

Schwab¹,

Moosmann²,

Dopf³

et al. 2015

Opt. Express

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“…Dipole nano-antennas, consisting of two metallic nanostructures separated by a dielectric gap region, can be viewed as MDM nanostructures. As the resonance frequency of dipole nano-antennas is sensitive to nanometer variations in the feedgap dimensions [27,28] and roughness [29,30], achieving arrays of such dipole antennas with uniform resonances is a challenge. Arrays of laterally-oriented dipole antennas invariably introduce a distribution of gap sizes, as well as 'shorted' antennas where the individual structures are connected together [31,32].…”

Section: Introductionmentioning

confidence: 99%

Fabrication of suspended metal–dielectric–metal plasmonic nanostructures

Dong¹,

Bosman²,

Zhu³

et al. 2014

Nanotechnology

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Dipole nano-antennas have predominantly been investigated in their lateral orientation with their long axes in plane with a supporting substrate. However, the response of coupled dipole antennas oriented vertically to a supporting substrate has so far been out of experimental reach. Here, we present a self-aligned electron-beam lithography technique for fabricating such antennas consisting of metal nanostructures on both sides of a suspended silicon nitride membrane. This 30 nm thick membrane provides an ultra-smooth metal/dielectric interface and uniformly defines the antenna feed-gap size in an array of antennas. It is also a suitable substrate for probing the nano-antenna response with monochromated electron energy-loss spectroscopy (EELS) in a transmission electron microscope. We provide details of this double-sided patterning process, and show the excitation of hybridized plasmon modes in EELS with electrons directed along, and at an angle to, the antenna axis.

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“…Some studies have evaluated the influence of shape variations of antennas produced using current nanofabrication technologies. [12][13][14] The optical response of these antennas, referred as realistic nanoantennas, is significantly different, since they do not consist of two ideal rectangular nanorods separated by a nanogap. Therefore, a more extensive study of such structures is of strong interest in order to optimize sensitivity, reliability, and estimate the limits of plasmonic biosensors.…”

mentioning

confidence: 99%

“…Other nanofabrication-related effects reported in a recent study can affect the spectral response of dipole plasmonic nanoantennas. 12 Based on the analysis of the antennas SEM images, we found a close relation between the decreasing trend of the antenna's arm aspect ratio (AR) (length/width), with respect to the design values, and the decrease of the resonance peak position, as can be noticed in the inset of between the aspect ratio and the plasmon resonance frequency (x res ) of an elongated particle can be addressed through a simple mass-and-spring model. 20 Accordingly,…”

mentioning

confidence: 99%

Spectral tunability of realistic plasmonic nanoantennas

Portela

Yano

Santschi

et al. 2014

Applied Physics Letters

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Single nanoantenna spectroscopy was carried out on realistic dipole nanoantennas with various arm lengths and gap sizes fabricated by electron-beam lithography. A significant difference in resonance wavelength between realistic and ideal nanoantennas was found by comparing their spectral response. Consequently, the spectral tunability (96 nm) of the structures was significantly lower than that of simulated ideal nanoantennas. These observations, attributed to the nanofabrication process, are related to imperfections in the geometry, added metal adhesion layer, and shape modifications, which are analyzed in this work. Our results provide important information for the design of dipole nanoantennas clarifying the role of the structural modifications on the resonance spectra, as supported by calculations.

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Investigating the influences of the precise manufactured shape of dipole nanoantennas on their optical properties

Cited by 7 publications

References 24 publications

Oxide mediated spectral shifting in aluminum resonant optical antennas

Oxide mediated spectral shifting in aluminum resonant optical antennas

Fabrication of suspended metal–dielectric–metal plasmonic nanostructures

Spectral tunability of realistic plasmonic nanoantennas

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