Transport and Quantum Coherence in Graphene Rings: Aharonov–Bohm Oscillations, Klein Tunneling, and Particle Localization

Filusch, Alexander; Wurl, Christian; Pieper, Andreas; Fehske, Holger

doi:10.1007/s10909-017-1839-2

Cited by 3 publications

(4 citation statements)

References 48 publications

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“…As a matter of course, imperfections will strongly influence the transport through contacted Dirac-cone systems [57,64,65]. This holds true even up to the point of complete suppression, e.g., by Anderson localisation [66].…”

Section: Disorder Effectsmentioning

confidence: 99%

“…Investigating the electronic properties of α − T 3 quantum dots in magnetic fields, we also start from such a description, and therefore must implement a boundary condition when the dot is cut out from the plane [39,54,55]. Of course, this approach has to be approved by comparison with lattice model results obtained numerically [55][56][57]. Addressing the transport behaviour of contacted dots and the influence of disorder on that we have to work with the full lattice model in any case.…”

Section: Introductionmentioning

confidence: 99%

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Electronic properties of α − 𝒯3 quantum dots in magnetic fields

Filusch

Fehske

2020

Eur. Phys. J. B

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We address the electronic properties of quantum dots in the two-dimensional α − 𝒯3 lattice when subjected to a perpendicular magnetic field. Implementing an infinite mass boundary condition, we first solve the eigenvalue problem for an isolated quantum dot in the low-energy, long-wavelength approximation where the system is described by an effective Dirac-like Hamiltonian that interpolates between the graphene (pseudospin 1/2) and Dice (pseudospin 1) limits. Results are compared to a full numerical (finite-mass) tight-binding lattice calculation. In a second step we analyse charge transport through a contacted α − 𝒯3 quantum dot in a magnetic field by calculating the local density of states and the conductance within the kernel polynomial and Landauer-Büttiker approaches. Thereby the influence of a disordered environment is discussed as well. Graphical abstract

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Section: Disorder Effectsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electronic properties of α − 𝒯3 quantum dots in magnetic fields

Filusch

Fehske

2020

Eur. Phys. J. B

Self Cite

View full text Add to dashboard Cite

show abstract

“…As a matter of course, imperfections will strongly influence the transport through contacted Dirac-cone systems [64,65,57]. This holds true even up to the point of complete suppression, e.g., by Anderson localisation [66].…”

Section: Disorder Effectsmentioning

confidence: 99%

“…Investigating the electronic properties of α − T 3 quantum dots in magnetic fields, we also start from such a description, and therefore must implement a boundary condition when the dot is cut out from the plane [54,39,55]. Of course, this approach has to be approved by comparison with lattice model results obtained numerically [56,55,57]. Addressing the transport behaviour of contacted dots and the influence of disorder on that we have to work with the full lattice model in any case.…”

Section: Introductionmentioning

confidence: 99%

Electronic Properties of $α-\mathcal{T}_3$ Quantum Dots in Magnetic Fields

Filusch,

Fehske

2020

Preprint

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We address the electronic properties of quantum dots in the two-dimensional α−T3 lattice when subjected to a perpendicular magnetic field. Implementing an infinite mass boundary condition, we first solve the eigenvalue problem for an isolated quantum dot in the low-energy, long-wavelength approximation where the system is described by an effective Dirac-like Hamiltonian that interpolates between the graphene (pseudospin 1/2) and Dice (pseudospin 1) limits. Results are compared to a full numerical (finite-mass) tight-binding lattice calculation. In a second step we analyse charge transport through a contacted α − T3 quantum dot in a magnetic field by calculating the local density of states and the conductance within the kernel polynomial and Landauer-Büttiker approaches. Thereby the influence of a disordered environment is discussed as well.

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Topological insulator ring with magnetic impurities

et al. 2018

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Topological insulators exhibit gapless edge or surface states that are topologically protected by time-reversal symmetry. However, several promising candidates for topologically insulating materials (such as Bi2Se3 and HgTe) contain spinful nuclei or other types of magnetic impurities that break time-reversal symmetry. We investigate the consequences of such impurities coupled to electronic edge states in a topological insulator quantum ring threaded by a magnetic flux. We use spin conservation and additional symmetry arguments to derive a universal formula for the spectrum of propagating edge modes in terms of the amplitude of transmission through the impurity. Our results apply for impurities of arbitrary spin. We show that there exists an energy regime in which the spectrum becomes nearly independent of the flux and significant spectral gaps form. We further analyze the electron-impurity entanglement entropy, finding that maximal entanglement occurs near the gaps in the spectrum. Our predictions can be investigated with quantum ring transport interference experiments or through spin-resolved STM measurements, providing a new approach to understand the role of impurities in topological insulator edge transport.

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Transport and Quantum Coherence in Graphene Rings: Aharonov–Bohm Oscillations, Klein Tunneling, and Particle Localization

Cited by 3 publications

References 48 publications

Electronic properties of α − 𝒯3 quantum dots in magnetic fields

Electronic properties of α − 𝒯3 quantum dots in magnetic fields

Electronic Properties of $α-\mathcal{T}_3$ Quantum Dots in Magnetic Fields

Topological insulator ring with magnetic impurities

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