Graphene nanoribbons: Photonic crystal waveguide analogy and minigap stripes

Bénisty, Henri

doi:10.1103/physrevb.79.155409

Cited by 30 publications

(22 citation statements)

References 39 publications

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“…Graphene has proved to have unique electronic and mechanical properties, 22 and has been more recently investigated also for photonics and optoelectronics. [23][24][25] In the field of (nano)plasmonics, so far most emphasis has been devoted to spectroscopy of plasmons in extended graphene, either doped or undoped, [26][27][28][29][30][31][32] and to the large lifetimes of their excitations compared to conventional metals. 30,33 Some interesting predictions, mostly based on macroscopic models, have been proposed for plasmonics in spatially-modulated graphene of micron and sub-micron size range.…”

mentioning

confidence: 99%

Optical Excitations and Field Enhancement in Short Graphene Nanoribbons

Cocchi

Prezzi

Ruini

et al. 2012

J. Phys. Chem. Lett.

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The optical excitations of elongated graphene nanoflakes of finite length are investigated theoretically through quantum chemistry semi-empirical approaches. The spectra and the resulting dipole fields are analyzed, accounting in full atomistic details for quantum confinement effects, which are crucial in the nanoscale regime. We find that the optical spectra of these nanostructures are dominated at low energy by excitations with strong intensity, comprised of characteristic coherent combinations of a few single-particle transitions with comparable weight. They give rise to stationary collective oscillations of the photoexcited carrier density extending throughout the flake, and to a strong dipole and field enhancement. This behavior is robust with respect to width and length variations, thus ensuring tunability in a large frequency range. The implications for nanoantennas and other nanoplasmonic applications are discussed for realistic geometries. TOC GraphicKeywords: nanoplasmonics, ZINDO, UV-vis spectrum, carbon nanostructures, transition density 2In the last few years remarkable interest has grown for nanoplasmonics and the perspectives it offers to merge electronics and photonics at the nanoscale. 1,2 A wide range of potential applications can be designed, including sensing and spectroscopic techniques, 3-6 fabrication of nanoantennas 7-11 and light emitters, 12,13 as well as beyond-THz optical devices or solar-energy conversion systems. [14][15][16] While great attention has been devoted to metal nanoparticles, due to the relative ease to produce them and to their possibility to support surface modes, 17-19 new materials and metamaterials are now being explored, 20,21 which, in addition to enhanced optical responses, are able to optimize circuit integration and reduce losses. Graphene has proved to have unique electronic and mechanical properties, 22 and has been more recently investigated also for photonics and optoelectronics. [23][24][25] In the field of (nano)plasmonics, so far most emphasis has been devoted to spectroscopy of plasmons in extended graphene, either doped or undoped, [26][27][28][29][30][31][32] and to the large lifetimes of their excitations compared to conventional metals. 30,33 Some interesting predictions, mostly based on macroscopic models, have been proposed for plasmonics in spatially-modulated graphene of micron and sub-micron size range. 32,[34][35][36][37][38] Here we focus on graphene in a completely different regime, typical of nanoscale structures, where an optical gap opens as a consequence of quantum confinement, and we show that field enhancement effects can also be seen. This regime has become particularly exciting in view of the recent production of controlled graphene wires by chemical routes. [39][40][41][42] We consider the case of self-standing elongated graphene nanoflakes (GNFs) with H-terminated edges, which we analyze by applying a fully-microscopic quantum-chemical approach. These flakes can be thought of as finite portions of armchair-edged graphene n...

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mentioning

confidence: 99%

Optical Excitations and Field Enhancement in Short Graphene Nanoribbons

Cocchi

Prezzi

Ruini

et al. 2012

J. Phys. Chem. Lett.

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“…Although the absolute values of the transmission and reflection coefficients in Eqs. (18) and (24) are different, the dispersion characteristics of two adjoining right-and left-handed dielectric layers, and the energetic spectrum diagrams of n − p junction in graphene are identical, as it is shown schematically in Fig. 3.…”

Section: Periodically-stripped Graphene Superlattices and Photonimentioning

confidence: 96%

Ballistic charge transport in graphene and light propagation in periodic dielectric structures with metamaterials: A comparative study

2013

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We explore the optical properties of periodic layered media containing left-handed metamaterials. This study is based on several analogies between the propagation of light in metamaterials and charge transport in graphene. We derive the conditions for these two problems become equivalent, i.e., the equations and the boundary conditions when the corresponding wave functions coincide. We show that the photonic band-gap structure of a periodic system built of alternating left-and right-handed dielectric slabs contains conical singularities similar to the Dirac points in the energy spectrum of charged quasiparticles in graphene. Such singularities in the zone structure of the infinite systems give rise to rather unusual properties of light transport in finite samples. In an insightful numerical experiment (the propagation of a Gaussian beam through a mixed stack of normal and meta-dielectrics) we simultaneously demonstrate four Dirac point-induced anomalies: (i) diffusionlike decay of the intensity at forbidden frequencies, (ii) focusing and defocussing of the beam, (iii) absence of the transverse shift of the beam, and (iv) a spatial analogue of the Zitterbewegung effect. All of these phenomena take place in media with non-zero average refractive index, and can be tuned by changing either the geometrical and electromagnetic parameters of the sample,or the frequency and the polarization of light.

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“…2(a)-(b). Due to the folding, the unstrained supercell shows crossings between modes in the same or in the opposite valley, it is important to note that the periodic potential could lift the degeneracy at these points 25 . A comparison between the left and right panels of Fig.…”

Section: B Strain Superlattice: 1d Gaussian Chainmentioning

confidence: 99%

“…It is well known that one-dimensional peri-odic potentials modify the electronic properties of bulk graphene producing anisotropic charge transport 21 , additional Dirac points 22 and a tunable band gap 23,24 . In addition, in graphene nanoribbons periodicity couples transverse modes promoting selective reflection 25 . From the experimental point of view, it has been shown the impressive capacity of depositing graphene on nanopatterned substrates [26][27][28][29] ; local measurements of the electronic properties have shown the appearance of pseudo-Landau levels in the strained regions providing direct evidence of the formation of strain superlattices 26 .…”

Section: Introductionmentioning

confidence: 99%

Valley notch filter in a graphene strain superlattice: Green's function and machine learning approach

et al. 2019

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The valley transport properties of a superlattice of out-of-plane Gaussians deformations are calculated using a Green's function and a Machine Learning approach. Our results show that periodicity significantly improves the valley filter capabilities of a single Gaussian deformation, these manifest themselves in the conductance as a sequence by valley filter plateaus. We establish that the physical effect behind the observed valley notch filter is the coupling between counter-propagating transverse modes; the complex relationship between the design parameters of the superlattice and the valley filter effect make difficult to estimate in advance the valley filter potentialities of a given superlattice. With this in mind, we show that a Deep Neural Network can be trained to predict valley transmission with a precision similar to the Green's function but with much less computational effort.

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Graphene nanoribbons: Photonic crystal waveguide analogy and minigap stripes

Cited by 30 publications

References 39 publications

Optical Excitations and Field Enhancement in Short Graphene Nanoribbons

Optical Excitations and Field Enhancement in Short Graphene Nanoribbons

Ballistic charge transport in graphene and light propagation in periodic dielectric structures with metamaterials: A comparative study

Valley notch filter in a graphene strain superlattice: Green's function and machine learning approach

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