Electron collimation at van der Waals domain walls in bilayer graphene

H. M. Abdullah; D. R. Da Costa; H. Bahlouli; A. Chaves; F. M. Peeters; B. Van Duppen

doi:10.1103/PhysRevB.100.045137

Electron collimation at van der Waals domain walls in bilayer graphene

H. M. Abdullah
, D. R. Da Costa
, H. Bahlouli
, A. Chaves
, F. M. Peeters
, B. Van Duppen

Department of Physics

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

We show that a domain wall separating single-layer graphene and AA-stacked bilayer graphene (AA-BLG) can be used to generate highly collimated electron beams which can be steered by a magnetic field. Two distinct configurations are studied, namely, locally delaminated AA-BLG and terminated AA-BLG whose terminal edge types are assumed to be either zigzag or armchair. We investigate the electron scattering using semiclassical dynamics and verify the results independently with wave-packet dynamics simulations. We find that the proposed system supports two distinct types of collimated beams that correspond to the lower and upper cones in AA-BLG. Our computational results also reveal that collimation is robust against the number of layers connected to AA-BLG and terminal edges.

Original language	English
Article number	045137
Journal	Physical Review B
Volume	100
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.100.045137
State	Published - 25 Jul 2019

Bibliographical note

Publisher Copyright:
© 2019 American Physical Society.

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.100.045137

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title = "Electron collimation at van der Waals domain walls in bilayer graphene",

abstract = "We show that a domain wall separating single-layer graphene and AA-stacked bilayer graphene (AA-BLG) can be used to generate highly collimated electron beams which can be steered by a magnetic field. Two distinct configurations are studied, namely, locally delaminated AA-BLG and terminated AA-BLG whose terminal edge types are assumed to be either zigzag or armchair. We investigate the electron scattering using semiclassical dynamics and verify the results independently with wave-packet dynamics simulations. We find that the proposed system supports two distinct types of collimated beams that correspond to the lower and upper cones in AA-BLG. Our computational results also reveal that collimation is robust against the number of layers connected to AA-BLG and terminal edges.",

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AU - Abdullah, H. M.

AU - Da Costa, D. R.

AU - Bahlouli, H.

AU - Chaves, A.

AU - Peeters, F. M.

AU - Van Duppen, B.

PY - 2019/7/25

Y1 - 2019/7/25

N2 - We show that a domain wall separating single-layer graphene and AA-stacked bilayer graphene (AA-BLG) can be used to generate highly collimated electron beams which can be steered by a magnetic field. Two distinct configurations are studied, namely, locally delaminated AA-BLG and terminated AA-BLG whose terminal edge types are assumed to be either zigzag or armchair. We investigate the electron scattering using semiclassical dynamics and verify the results independently with wave-packet dynamics simulations. We find that the proposed system supports two distinct types of collimated beams that correspond to the lower and upper cones in AA-BLG. Our computational results also reveal that collimation is robust against the number of layers connected to AA-BLG and terminal edges.

AB - We show that a domain wall separating single-layer graphene and AA-stacked bilayer graphene (AA-BLG) can be used to generate highly collimated electron beams which can be steered by a magnetic field. Two distinct configurations are studied, namely, locally delaminated AA-BLG and terminated AA-BLG whose terminal edge types are assumed to be either zigzag or armchair. We investigate the electron scattering using semiclassical dynamics and verify the results independently with wave-packet dynamics simulations. We find that the proposed system supports two distinct types of collimated beams that correspond to the lower and upper cones in AA-BLG. Our computational results also reveal that collimation is robust against the number of layers connected to AA-BLG and terminal edges.

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Electron collimation at van der Waals domain walls in bilayer graphene

Abstract

Bibliographical note

ASJC Scopus subject areas

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