Metrology and microscopic picture of the integer quantum Hall effect

Weis, J.; Klitzing, K. von

doi:10.1098/rsta.2011.0198

Cited by 99 publications

(95 citation statements)

References 36 publications

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“…4 More precisely, the edge channels are regarded as "incompressible strips" owing to the electron screening. [5][6][7] Although the nature of the QHE state is successfully explained by the topological rigidity, details of the state in nonequilibrium are largely unexplored. Recent experiments aimed at quantum information processing by using edge channels, involving phase reversal of electrons in electron interferometers, 8,9 decoherence, 10-15 energy relaxation, [16][17][18] and dynamics of the edge magnetoplasmons in the edge channels, 19,20 have clarified electron behaviors in the nonequilibrium QHE state.…”

Section: Introductionmentioning

confidence: 99%

Observation of finite excess noise in the voltage-biased quantum Hall regime as a precursor for breakdown

et al. 2013

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We performed noise measurements in a two-dimensional electron gas to investigate the nonequilibrium quantum Hall effect (QHE) state. While excess noise is perfectly suppressed around the zero-biased QHE state reflecting the dissipationless electron transport of the QHE state, considerable finite excess noise is observed in the breakdown regime of the QHE. The noise temperature deduced from the excess noise is found to be of the same order as the energy gap between the highest occupied Landau level and the lowest empty one. Moreover, unexpected finite excess noise is observed at a finite source-drain bias voltage smaller than the onset voltage of the QHE breakdown, which indicates finite dissipation in the QHE state and may be related to the prebreakdown of the QHE.

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Section: Introductionmentioning

confidence: 99%

Observation of finite excess noise in the voltage-biased quantum Hall regime as a precursor for breakdown

et al. 2013

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“…In particular, graphene's hard wall confining potential has been predicted to result in charge accumulation near physical edges under electrostatic gating [8], which has been used to explain observations in several transport [9][10][11][12] and imaging [13] experiments. In the QH regime where the edges play a crucial role as the connection between bulk state and transport [14][15][16][17][18], how such charge accumulation affects transport quantization remains elusive [11,12,19]. A comprehensive understanding requires a detailed study by both transport and bulk-sensitive techniques on the same gated hall bar.…”

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confidence: 99%

“…Our results can be explained selfconsistently within either model, and our conclusions on how to refine transport-based analysis of QH effect in graphene (which will be discussed later in the paper) do not depend on the model choice. To facilitate our discussion, we work in the incompressible state picture (for a review, see [18] and references therein). The essence of this picture is that the dissipationless transport current flows only in the incompressible regions, hence the transport quantization depends on the spatial structure of such regions.…”

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confidence: 99%

“…Integration of the current density over the entire incompressible region gives rise to a quantized transverse Hall conductance determined by the Landau level filling factor ν in the incompressible region. In a Hall bar geometry, the conditions to measure a quantized conductance νh/e 2 are: 1) the incompressible regions at filling factor ν are able to percolate through the sample and connect to the current leads, and 2) the voltage probes are able to achieve a full equilibration in chemical potential with the boundaries of these incompressible regions [17,18].…”

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confidence: 99%

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Unconventional Correlation between Quantum Hall Transport Quantization and Bulk State Filling in Gated Graphene Devices

et al. 2016

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We report simultaneous transport and scanning Microwave Impedance Microscopy to examine the correlation between transport quantization and filling of the bulk Landau levels in the quantum Hall regime in gated graphene devices. Surprisingly, comparison of these measurements reveals that quantized transport typically occurs below complete filling of bulk Landau levels, when the bulk is still conductive. This result points to a revised understanding of transport quantization when carriers are accumulated by gating. We discuss the implications on transport study of the quantum Hall effect in graphene and related topological states in other two dimensional electron systems.

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“…In QHE, the Hall resistance of a two-dimensional (2D) system of charge carriers as a function of magnetic field or charge carrier density shows well-defined quantized plateaus at R H,ν = R K /ν, where R K = h/e 2 is the von Klitzing constant, h is the Planck constant, e is the elementary charge, and ν is an integer [4].…”

Section: Introductionmentioning

confidence: 99%

Mini array of quantum Hall devices based on epitaxial graphene

Новиков

Лебедева

Hämäläinen

et al. 2016

Journal of Applied Physics

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Series connection of four quantum Hall effect (QHE) devices based on epitaxial graphene films was studied for realization of a quantum resistance standard with an up-scaled value. The tested devices showed quantum Hall plateaux R H,2 at filling factor ν = 2 starting from relatively low magnetic field (between 4 T and 5 T) when temperature was 1.5 K. Precision measurements of quantized Hall resistance of four QHE devices connected by triple series connections and external bonding wires were done at B = 7 T and T = 1.5 K using a commercial precision resistance bridge with 50 μA current through the QHE device.The results showed that the deviation of the quantized Hall resistance of the series connection of four graphene-based QHE devices from the expected value of 4×R H,2 = 2h/e 2 was smaller than the relative standard uncertainty of the measurement (< 1×10 -7 ) limited by the used resistance bridge.

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Metrology and microscopic picture of the integer quantum Hall effect

Cited by 99 publications

References 36 publications

Observation of finite excess noise in the voltage-biased quantum Hall regime as a precursor for breakdown

Observation of finite excess noise in the voltage-biased quantum Hall regime as a precursor for breakdown

Unconventional Correlation between Quantum Hall Transport Quantization and Bulk State Filling in Gated Graphene Devices

Mini array of quantum Hall devices based on epitaxial graphene

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