Mie scattering analog in graphene: Lensing, particle confinement, and depletion of Klein tunneling

Heinisch, R. L.; Bronold, F. X.; Fehske, Holger

doi:10.1103/physrevb.87.155409

Cited by 81 publications

(107 citation statements)

References 33 publications

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“…In this regime resonances in the conductance [7,8] and the scattering cross section [9] indicate quasibound states at the dot. Indeed, electrons can be confined in a circular dot surrounded by unbiased graphene as the classical electron dynamics in the dot is integrable and the corresponding Dirac equation is separable [7,10].…”

mentioning

confidence: 99%

“…Figure 2 shows our results for E/V < 1 (entailing negative refractive index). For comparison with the continuum model for plane wave scattering, we plot in the upper panel the scattering efficiency Q, that is the scattering cross section divided by the geometric cross section, calculated in the Dirac approximation (for details of the calculation see [9]). A series of resonances a m appears in Q, due to the excitation of normal modes of the dot.…”

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confidence: 99%

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Electron dynamics in graphene with gate-defined quantum dots

Pieper

Heinisch

Fehske

2013

EPL

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-We use numerically exact Chebyshev expansion and kernel polynomial methods to study transport through circular graphene quantum dots in the framework of a tight-binding honeycomb lattice model. Our focus lies on the regime where individual modes of the electrostatically defined dot dominate the charge carrier dynamics. In particular, we discuss the scattering of an injected Dirac electron wave packet for a single quantum dot, electron confinement in the dot, the optical excitation of dot-bound modes, and the propagation of an electronic excitation along a linear array of dots.

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confidence: 99%

mentioning

confidence: 99%

Electron dynamics in graphene with gate-defined quantum dots

Pieper

Heinisch

Fehske

2013

EPL

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“…But, while Klein-tunneling is responsible for the high mobility resulting from the suppression of backscattering, it also makes it difficult to control or shut off carrier-motion, to the detriment of electronic switching. We show that it is possible to control the charge-carriers with a circular p-n junction consisting of a central region acting as a circular potential barrier 22,23 . The junction is created by combining a planar back-gate with a top-gate consisting of an Au decorated tip and it can be continuously tuned from the nanometer to the micrometer scale.…”

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confidence: 99%

“…Its radius, , grows with increasing and diverges at the bulk charge-neutrality point, beyond which it disappears. In graphene the reflection of electrons at a p-n junction is governed by Klein scattering which, for certain oblique angles, can produce perfect reflection 19,23 . As a result, the cavity can support…”

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Tuning a circular p–n junction in graphene from quantum confinement to optical guiding

et al. 2017

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“…It has previously been shown that the DE on this form can be used to calculate the band structure of GALs [11,12]. In addition, the DE has previously been used to calculate scattering of Dirac electrons on a single circular mass barrier [32], a single circular electrostatic barrier [33] and simple barriers of constant and finite mass [34]. The advantages of our approach are that it works for any antidot shape and for an arbitrary arrangement of antidots.…”

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Dirac model of electronic transport in graphene antidot barriers

Thomsen¹,

Brun²,

Pedersen³

2014

J. Phys.: Condens. Matter

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Abstract. In order to use graphene for semiconductor applications, such as transistors with high on/off ratios, a band gap must be introduced into this otherwise semimetallic material. A promising method of achieving a band gap is by introducing nanoscale perforations (antidots) in a periodic pattern, known as a graphene antidot lattice (GAL). A graphene antidot barrier (GAB) can be made by introducing a 1D GAL strip in an otherwise pristine sheet of graphene. In this paper, we will use the Dirac equation (DE) with a spatially varying mass term to calculate the electronic transport through such structures. Our approach is much more general than previous attempts to use the Dirac equation to calculate scattering of Dirac electrons on antidots. The advantage of using the DE is that the computational time is scale invariant and our method may therefore be used to calculate properties of arbitrarily large structures. We show that the results of our Dirac model are in quantitative agreement with tight-binding for hexagonal antidots with armchair edges. Furthermore, for a wide range of structures, we verify that a relatively narrow GAB, with only a few antidots in the unit cell, is sufficient to give rise to a transport gap.

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Mie scattering analog in graphene: Lensing, particle confinement, and depletion of Klein tunneling

Cited by 81 publications

References 33 publications

Electron dynamics in graphene with gate-defined quantum dots

Electron dynamics in graphene with gate-defined quantum dots

Tuning a circular p–n junction in graphene from quantum confinement to optical guiding

Dirac model of electronic transport in graphene antidot barriers

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