We use numerical simulations to predict peculiar magnetotransport
fingerprints in polycrystalline graphene, driven by the presence of grain
boundaries of varying size and orientation. The formation of Landau levels is
shown to be restricted by the polycrystalline morphology, requiring the
magnetic length to be smaller than the average grain radius. The nature of
localization is also found to be unusual, with strongly localized states at the
center of Landau levels (including the usually highly robust zero-energy state)
and extended electronic states lying between Landau levels. These extended
states percolate along the network of grain boundaries, resulting in a finite
value for the bulk dissipative conductivity and suppression of the quantized
Hall conductance. Such breakdown of the quantum Hall regime provoked by
extended structural defects is also illustrated through two-terminal
Landauer-B\"uttiker conductance calculations, indicating how a single grain
boundary induces cross-linking between edge states lying at opposite sides of a
ribbon geometry

Cresti, Alessandro

Cummings, Aron W.

Roche, Stephan

English

arXiv

International audienceWe use numerical simulations to predict peculiar magnetotransport fingerprints in polycrystalline graphene,driven by the presence of grain boundaries of varying size and orientation. The formation of Landau levelsis shown to be restricted by the polycrystalline morphology, requiring the magnetic length to be smaller thanthe average grain radius. The nature of localization is also found to be unusual, with strongly localized statesat the center of Landau levels (including the usually highly robust zero-energy state) and extended electronicstates lying between Landau levels. These extended states percolate along the network of grain boundaries,resulting in a finite value for the bulk dissipative conductivity and suppression of the quantized Hall conductance.Such breakdown of the quantum Hall regime provoked by extended structural defects is also illustrated throughtwo-terminal Landauer-B ̈uttiker conductance calculations, indicating how a single grain boundary induces crosslinking between edge states lying at opposite sides of a ribbon geometry

Cummings, Aron

Hal - Université Grenoble Alpes

Quantum Hall effect in polycrystalline graphene: The role of grain boundaries

We use numerical simulations to predict peculiar magnetotransport fingerprints in polycrystalline graphene, driven by the presence of grain boundaries of varying size and orientation. The formation of Landau levels is shown to be restricted by the polycrystalline morphology, requiring the magnetic length to be smaller than the average grain radius. The nature of localization is also found to be unusual, with strongly localized states at the center of Landau levels (including the usually highly robust zero-energy state) and extended electronic states lying between Landau levels. These extended states percolate along the network of grain boundaries, resulting in a finite value for the bulk dissipative conductivity and suppression of the quantized Hall conductance. Such breakdown of the quantum Hall regime provoked by extended structural defects is also illustrated through two-terminal Landauer-Büttiker conductance calculations, indicating how a single grain boundary induces cross linking between edge states lying at opposite sides of a ribbon geometry

Quantum Hall effect in polycrystalline graphene: The role of grain boundaries

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