Experimental Review of Graphene

Cooper, Daniel R.; D’Anjou, Benjamin; Ghattamaneni, Nageswara R.; Harack, Benjamin; Hilke, Michael; Horth, Alexandre; Majlis, Norberto; Massicotte, Mathieu; Vandsburger, Leron; Whiteway, Eric; Yu, Victor

doi:10.5402/2012/501686

Cited by 494 publications

(374 citation statements)

References 210 publications

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“…The availability of techniques suitable for the simulation of large-area graphene structures is also essential for a direct comparison with transport and noise measurements performed on micron-sized flakes (see for example Refs. [23][24][25][26]). …”

Section: Introductionmentioning

confidence: 99%

High-performance solution of the transport problem in a graphene armchair structure with a generic potential

et al. 2014

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We propose an efficient numerical method to study the transport properties of armchair graphene ribbons in the presence of a generic external potential. The method is based on a continuum envelope-function description with physical boundary conditions. The envelope functions are computed in the reciprocal space, and the transmission is then obtained with a recursive scattering matrix approach. This allows a significant reduction of the computational time with respect to finite difference simulations.

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Section: Introductionmentioning

confidence: 99%

High-performance solution of the transport problem in a graphene armchair structure with a generic potential

et al. 2014

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“…These unique characteristics lead to numerous of extraordinary new phenomena in graphene such as the Klein tunneling 5 , the ambipolar field effect 1,6 , the finite minimum conductivity 2,7 , the ultra-high mobility 8,9 , and the anomalous quantum Hall effect 2,10 . With these novel properties 11,12 , graphene presents itself as an extremely promising candidatematerial for future generation of electronics 13,14 .…”

Section: Introductionmentioning

confidence: 99%

Plasmonic excitations in Coulomb-coupledN-layer graphene structures

2013

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We study Dirac plasmons and their damping in spatially separated N -layer graphene structures at finite doping and temperatures. The plasmon spectrum consists of one optical excitation with a square-root dispersion and N − 1 acoustical excitations with linear dispersions, which are undamped at zero temperature within a triangular energy region outside the electron-hole continuum. For any finite number of graphene layers we have found that the energy and weight of the optical plasmon increase in the long wavelength limit, respectively, as square-root and linear functions of N . This is in agreement with recent experimental findings. With an increase of the number of multilayer acoustical plasmon modes, the energy and weight of the upper lying branches also exhibit an enhancement with N . This increase is strongest for the uppermost acoustical mode so that its energy can exceed at some value of momentum the plasmon energy in an individual graphene sheet. Meanwhile, the energy of the low lying acoustical branches decreases weakly with N as compared with the single acoustical mode in double-layer graphene structures. Our numerical calculations provide a detailed understanding of the overall behavior of the wave vector dependence of the optical and acoustical multilayer plasmon modes and show how their dispersion and damping are modified as a function of temperature, interlayer spacing, and inlayer carrier density in (un)balanced graphene multilayer structures.

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“…In fact, graphene can conduct electricity more effectively than copper, which implicates great potential and prospects for countless technological applications. Peculiar aspects of conductivity [7][8][9] and special mobility, [10][11][12][13] magnetotransport, and quantum Hall effect [1] have been investigated.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3][4][5][6] Graphene films are endowed with amazing mechanical, thermal, electrical, magnetical, and optical characteristics, resulting from the remarkable hexagonal lattice of carbon atoms shaped by a substrate of r-bonds, in which electrons are hybridized in an sp 2 configuration.…”

Section: Introductionmentioning

confidence: 99%

Polygonal current models for polycyclic aromatic hydrocarbons and graphene sheets of various shapes

Pelloni

Lazzeretti

2017

J Comput Chem

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Assuming that graphene is an "infinite alternant" polycyclic aromatic hydrocarbon resulting from tessellation of a surface by only six-membered carbon rings, planar fragments of various size and shape (hexagon, triangle, rectangle, and rhombus) have been considered to investigate their response to a magnetic field applied perpendicularly. Allowing for simple polygonal current models, the diatropicity of a series of polycyclic textures has been reliably determined by comparing quantitative indicators, the p-electron contribution to I B , the magnetic field-induced current susceptibility of the peripheral circuit, to n k and to r k ðCMÞ52NICS k ðCMÞ, respectively the out-of-plane components of the magnetizability tensor and of the magnetic shielding tensor at the center of mass. Extended numerical tests and the analysis based on the polygonal model demonstrate that (i) n k and r k ðCMÞ yield inadequate and sometimes erroneous measures of diatropicity, as they are heavily flawed by spurious geometrical factors, (ii) I B values computed by simple polygonal models are valid quantitative indicators of aromaticity on the magnetic criterion, preferable to others presently available, whenever current susceptibility cannot be calculated ab initio as a flux integral, (iii) the hexagonal shape is the most effective to maximize the strength of p-electron currents over the molecular perimeter, (iv) the edge current strength of triangular and rhombic graphene fragments is usually much smaller than that of hexagonal ones, (v) doping by boron and nitrogen nuclei can regulate and even inhibit peripheral ring currents, (vi) only for very large rectangular fragments can substantial current strengths be expected.

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Experimental Review of Graphene

Cited by 494 publications

References 210 publications

High-performance solution of the transport problem in a graphene armchair structure with a generic potential

High-performance solution of the transport problem in a graphene armchair structure with a generic potential

Plasmonic excitations in Coulomb-coupledN-layer graphene structures

Polygonal current models for polycyclic aromatic hydrocarbons and graphene sheets of various shapes

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