Valley Hall effect and nonlocal resistance in locally gapped graphene

Thomas Aktor; Jose H. Garcia; Stephan Roche; Antti Pekka Jauho; Stephen R. Power

doi:10.1103/PhysRevB.103.115406

Valley Hall effect and nonlocal resistance in locally gapped graphene

Thomas Aktor
, Jose H. Garcia
, Stephan Roche
, Antti Pekka Jauho
, Stephen R. Power^*

^*Corresponding author for this work

Catalan Institute of Nanoscience and Nanotechnology
Trinity College Dublin

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

We report on the emergence of bulk, valley-polarized currents in graphene-based devices, driven by spatially varying regions of broken sublattice symmetry, and revealed by nonlocal resistance (RNL) fingerprints. By using a combination of quantum transport formalisms, giving access to bulk properties as well as multiterminal device responses, the presence of a nonuniform local band gap is shown to give rise to valley-dependent scattering and a finite Fermi-surface contribution to the valley Hall conductivity, related to characteristics of RNL. These features are robust against disorder and provide a plausible interpretation of controversial experiments in graphene/hexagonal boron nitride superlattices. Our findings suggest both an alternative mechanism for the generation of valley Hall effect in graphene and a route towards valley-dependent electron optics, by materials and device engineering.

Original language	English
Article number	115406
Journal	Physical Review B
Volume	103
Issue number	11
Number of pages	6
ISSN	2469-9950
DOIs	https://doi.org/10.1103/PhysRevB.103.115406
Publication status	Published - 2021

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title = "Valley Hall effect and nonlocal resistance in locally gapped graphene",

abstract = "We report on the emergence of bulk, valley-polarized currents in graphene-based devices, driven by spatially varying regions of broken sublattice symmetry, and revealed by nonlocal resistance (RNL) fingerprints. By using a combination of quantum transport formalisms, giving access to bulk properties as well as multiterminal device responses, the presence of a nonuniform local band gap is shown to give rise to valley-dependent scattering and a finite Fermi-surface contribution to the valley Hall conductivity, related to characteristics of RNL. These features are robust against disorder and provide a plausible interpretation of controversial experiments in graphene/hexagonal boron nitride superlattices. Our findings suggest both an alternative mechanism for the generation of valley Hall effect in graphene and a route towards valley-dependent electron optics, by materials and device engineering.",

author = "Thomas Aktor and Garcia, \{Jose H.\} and Stephan Roche and Jauho, \{Antti Pekka\} and Power, \{Stephen R.\}",

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journal = "Physical Review B",

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AU - Aktor, Thomas

AU - Garcia, Jose H.

AU - Roche, Stephan

AU - Jauho, Antti Pekka

AU - Power, Stephen R.

PY - 2021

Y1 - 2021

N2 - We report on the emergence of bulk, valley-polarized currents in graphene-based devices, driven by spatially varying regions of broken sublattice symmetry, and revealed by nonlocal resistance (RNL) fingerprints. By using a combination of quantum transport formalisms, giving access to bulk properties as well as multiterminal device responses, the presence of a nonuniform local band gap is shown to give rise to valley-dependent scattering and a finite Fermi-surface contribution to the valley Hall conductivity, related to characteristics of RNL. These features are robust against disorder and provide a plausible interpretation of controversial experiments in graphene/hexagonal boron nitride superlattices. Our findings suggest both an alternative mechanism for the generation of valley Hall effect in graphene and a route towards valley-dependent electron optics, by materials and device engineering.

AB - We report on the emergence of bulk, valley-polarized currents in graphene-based devices, driven by spatially varying regions of broken sublattice symmetry, and revealed by nonlocal resistance (RNL) fingerprints. By using a combination of quantum transport formalisms, giving access to bulk properties as well as multiterminal device responses, the presence of a nonuniform local band gap is shown to give rise to valley-dependent scattering and a finite Fermi-surface contribution to the valley Hall conductivity, related to characteristics of RNL. These features are robust against disorder and provide a plausible interpretation of controversial experiments in graphene/hexagonal boron nitride superlattices. Our findings suggest both an alternative mechanism for the generation of valley Hall effect in graphene and a route towards valley-dependent electron optics, by materials and device engineering.

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DO - 10.1103/PhysRevB.103.115406

M3 - Journal article

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SN - 2469-9950

VL - 103

JO - Physical Review B

JF - Physical Review B

IS - 11

M1 - 115406

ER -

Valley Hall effect and nonlocal resistance in locally gapped graphene

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