Fractal Nanoparticle Plasmonics: The Cayley Tree

Gottheim, Samuel; Zhang, Hui; Govorov, Alexander O.; Halas, Naomi J.

doi:10.1021/acsnano.5b00412

Cited by 106 publications

(119 citation statements)

References 32 publications

(48 reference statements)

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“…In principle an electrically connected network can be made in this way. This design is somewhat similar to fractal antennas 33, 34 . However, while fractals are generated by subdividing or filling a given area with ever smaller features, in our design the typical element size remains the same, but the full antenna size grows linearly with generation.…”

Section: Dendritic Antenna Designmentioning

confidence: 99%

Dendritic optical antennas: scattering properties and fluorescence enhancement

Antoncecchi

Zheng

et al. 2017

Sci Rep

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With the development of nanotechnologies, researchers have brought the concept of antenna to the optical regime for manipulation of nano-scaled light matter interactions. Most optical nanoantennas optimize optical function, but are not electrically connected. In order to realize functions that require electrical addressing, optical nanoantennas that are electrically continuous are desirable. In this article, we study the optical response of a type of electrically connected nanoantennas, which we propose to call “dendritic” antennas. While they are connected, they follow similar antenna hybridization trends to unconnected plasmon phased array antennas. The optical resonances supported by this type of nanoantennas are mapped both experimentally and theoretically to unravel their optical response. Photoluminescence measurements indicate a potential Purcell enhancement of more than a factor of 58.

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Section: Dendritic Antenna Designmentioning

confidence: 99%

Dendritic optical antennas: scattering properties and fluorescence enhancement

Antoncecchi

Zheng

et al. 2017

Sci Rep

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“…In the limit where the process is repeated to infinity, the Hilbert curve fully fills the 2D plane, while remaining essentially one-dimensional. Owing to its hierarchical structuring, the [46]. Here, we demonstrate wideband operation of a single-layer graphene absorber with a Hilbert design.…”

Section: Introductionmentioning

confidence: 99%

“…Examples include multiband antenna arrays [40], high impedance metasurfaces [41], isotropic broadband metamaterials [42], transparent electrodes [43], and substrates for surface enhanced Raman scattering [44]. Moreover, metallic metasurfaces with Hilbert curve and other fractal designs have been combined with graphene, in order to realize absorbers [45] and photodetectors [46]. Here, we demonstrate wideband operation of a single-layer graphene absorber with a Hilbert design.…”

mentioning

confidence: 98%

Self-Affine Graphene Metasurfaces for Tunable Broadband Absorption

Papasimakis

Tsai

2016

Phys. Rev. Applied

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Graphene has emerged as a promising platform for THz metasurfaces supporting electrically tunable deep-subwavelength plasmonic excitations. Here, we introduce a broadband graphene metasurface based on the Hilbert curve, a continuous, space-filling fractal. We demonstrate enhancement of graphene absorption over a broad frequency band (0.5-60 THz) with an average absorption level exceeding 20%. Owing to the continuous nature of the metasurface patterns, both absorption level and bandwidth can be controlled electrically by varying the graphene charge carrier concentration.Keywords: graphene plasmonics, fractal metasurfaces, broadband absorber 2 Structuring materials [1][2][3][4] at the subwavelength scale has led to the emergence of metamaterials [5][6][7], a paradigm shift in the design of artificial electromagnetic materials [8] resulting in technologically important, as well as exotic, applications, including perfect lenses [9], transformation optics and invisibility cloaks [10], and perfect absorbers [11]. The properties of metamaterials largely arise from resonant dispersion; hence material loss restricts the strength [12] and bandwidth of the metamaterial response [13].In particular, with respect to perfect absorbers, various schemes have been suggested in order to achieve strong absorption in gigahertz [14] [25]. However, such methods often result in complex, bulky configurations, with little tunability. Graphene, a monolayer of carbon atoms, provides an appealing alternative: owing to its band structure, graphene supports plasmonic excitations at the deep sub-wavelength scale [26]. Plasmonic resonators can be realized by structuring graphene at the nanoscale [27][28][29], which can then be employed to construct graphene metasurfaces targeting the THz part of the spectrum [30][31][32][33][34]. At the same time the high sensitivity of the electromagnetic properties of graphene to the charge carrier [35] concentration provides means of electrical control of plasmons [36][37][38]. In 3 addition to tunability, graphene as a plasmonic material allows to strongly confine electromagnetic radiation to much smaller physical volumes compared to typical metals.For example, the plasmon wavelength for graphene is about 50 times smaller than the free-space wavelength, while for noble metals this is an order of magnitude smaller [26,29]. Such strong field confinement allows people to realize very complex graphene structures while retaining a subwavelength footprint. Graphene exhibits broadband nonlinearities and high thermal conductivity, whereas its atomic thickness facilitates device integration.Here, we introduce fractal graphene metasurfaces as tunable, broadband THz absorbers of monoatomic thickness (see Fig. 1(a)). We demonstrate multifold enhancement of absorption over an extremely broad frequency band, where average absorption levels exceed 20% from 0.5 to 60 THz in strongly doped graphene. We show that the absorption band is strongly dependent on the charge carrier concentration enabling dynamic electrosta...

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“…However, non-spherical nanostructures have received growing interest due to unique spectral lineshapes and features that cannot be achieved by spherical particles such as nanotriangles, nanocubes, and nanostars [13][14][15]. Recently, a successful fractal structure in Y-shape formation was introduced for microwave frequencies and near-infrared region to support strong plasmon resonant modes with multifrequency electromagnetic response [16,17]. In addition, the fractal order of the Yshape structure excites a number of plasmonic modes.…”

Section: Introductionmentioning

confidence: 99%

Fractal aluminum Cayley-trees to design plasmonic ultraviolet photodetectors

et al. 2016

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Plasmonic ultraviolet (UV) photodetectors have witnessed ongoing and tremendous enhancements in quantum efficiency and responsivity. Here, we go beyond regular plasmonic detectors by using periodic arrays of fractal aluminum nanostructures as Cayley trees deposited on a Ga 2 O 3 substrate to generate photocurrent. We show that the proposed aluminum Cayley trees are able to support and intensify strong broad plasmon resonant modes across the UV to the visible spectrum. It is shown that the Cayley trees can be tailored to facilitate strong absorption at high energies (short wavelengths), resulting formation of hot carriers. Having perfect compatibility to operate at the UV spectrum, fractal aluminum structures and Ga 2 O 3 substrate help to increase the produced photocurrent remarkably. Presence of Ga 2 O 3 layer blue-shifts the peak of absorption to higher energies and helps to generate hot carriers at deeper UV wavelengths.

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Fractal Nanoparticle Plasmonics: The Cayley Tree

Cited by 106 publications

References 32 publications

Dendritic optical antennas: scattering properties and fluorescence enhancement

Dendritic optical antennas: scattering properties and fluorescence enhancement

Self-Affine Graphene Metasurfaces for Tunable Broadband Absorption

Fractal aluminum Cayley-trees to design plasmonic ultraviolet photodetectors

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