A new transport regime in the quantum Hall effect

Shahar, D.; Hilke, Michael; Li, C. C.; Tsui, D. C.; Sondhi, S. L.; Cunningham, J. E.; Razeghi, Manijeh

doi:10.1016/s0038-1098(98)00157-4

Cited by 108 publications

(115 citation statements)

References 19 publications

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“…Quantitative analysis closer to the MI transition will require lower temperature experiments in order to continue to capture the interplay of the Coulomb gap and quantum fluctuation physics. We note, that unlike the phenomenology near the quantum Hall-to-insulator transition [19], scaling here remains critical. The ability to treat the insulator on an equal footing with the metal Carrier density n for each data set is indicated in the legend in units of 10 19 cm ÿ3 .…”

Section: Volume 89 Number 27 P H Y S I C a L R E V I E W L E T T E R Smentioning

confidence: 63%

Quantum Fluctuations and the Closing of the Coulomb Gap in a Correlated Insulator

et al. 2002

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The ''switchable mirror'' yttrium hydride is one of the few strongly correlated systems with a continuous Mott-Hubbard metal-insulator transition. We systematically map out the low temperature electrical transport from deep in the insulator to the quantum critical point using persistent photoconductivity as a drive parameter. Both activated hopping over a Coulomb gap and power-law quantum fluctuations must be included to describe the data. Collapse of the data onto a universal curve within a dynamical scaling framework (with corrections) requires z 6:0 0:5, where and z are the static and dynamical critical exponents, respectively. DOI: 10.1103/PhysRevLett.89.276402 PACS numbers: 71.30.+h, 71.27.+a, 72.20.-i, 73.50.-h The metal-insulator (MI) transition is only defined properly at temperature T 0, where the electrical conductivity is identically zero in the insulator and assumes a finite value in the metal. Nonetheless, experiments at finite temperature can reveal fundamental properties of the transition by probing quantum fluctuations in the immediate vicinity of the T 0 critical point [1]. Quantum fluctuations inextricably link the static and dynamical response [2], and have led to predictions for new exponents and scaling forms [3] for T; n on both sides of the MI transition. Here n is the distance from the quantum critical point for a transition tuned by electron density, pressure, magnetic field, or any such nonthermal means.The T 0 MI transition in the limit of strong electronelectron correlations has remained resistant to both theoretical understanding and experimental characterization. Progress in this direction would be welcome for illuminating the Mott-Hubbard MI transition itself as well as for shedding light on the physics of cuprate superconductors, colossal magnetoresistance perovskites, rare earth actinides, and transition metal oxides. Moreover, systematic studies of the development of correlations and fluctuations in the insulator are sorely lacking when compared to investigations of the metal. We address these shortcomings through a high-resolution study of the insulating state in yttrium hydride as we approach the T 0 MI transition through successive illuminations under ultraviolet light. Unlike most highly correlated materials, YH x does not have a first-order structural phase transition that cuts off the critical behavior. It retains a continuous Mott-Hubbard MI transition, permitting full access to the quantum critical point.Yttrium hydride and lanthanum hydride are the original ''switchable mirrors' ' [4] with remarkable electronic and optical properties [5]. The reversible transition from shiny, metallic dihydride to transparent, insulating trihydride can be triggered at room temperature simply by changing the surrounding hydrogen gas pressure or an electrolytic cell potential [6]. A wide range of possible applications follows, from solid state displays to smart windows. A key aspect of the technology is the opening of an optical gap of order 3 eV in the insulator [7] -a Hubbard gap -...

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Section: Volume 89 Number 27 P H Y S I C a L R E V I E W L E T T E R Smentioning

confidence: 63%

Quantum Fluctuations and the Closing of the Coulomb Gap in a Correlated Insulator

et al. 2002

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“…We compare these results with the known facts for the PIT in IQHE. 17,[19][20][21][22]24,[82][83][84][85] We find that, like at PIT in IQHE, the graphs of ρ xx as function of electron density, recorded at different temperatures, intersect at one single critical point, and they collapse into a single curve after a single-parameter rescaling. The scaling exponent κ is in good agreement with what one would predict by using the universally accepted value of the finite-size scaling exponent ν = 2.58 ± 0.03, 54,[86][87][88][89][90][91] and with p fixed like in our simulations (p = 1).…”

Section: Introductionmentioning

confidence: 61%

Quantum criticality at the Chern-to-normal insulator transition

Xue

Prodan

2013

Phys. Rev. B

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Using the non-commutative Kubo formula for aperiodic solids and a recently developed numerical implementation, we study the conductivity σ and resistivity ρ tensors as functions of Fermi level E F and temperature T, for models of strongly disordered Chern insulators. The formalism enabled us to converge the transport coefficients at temperatures low enough to enter the quantum critical regime at the Chern-to-trivial insulator transition. We find that the ρ xx -curves at different temperatures intersect each other at one single critical point, and that they obey a single-parameter scaling law with an exponent close to the universally accepted value for the unitary symmetry class. However, when compared with the established experimental facts on the plateau-insulator transition in the Integer Quantum Hall Effect, we find a universal critical conductance σ c xx twice as large, an ellipse rather than a semi-circle law, and absence of the Quantized Hall Insulator phase.

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“…Non-universal exponents were observed in the dependence of the transition width on temperature [15], current [16] and frequency [17]. Other experiments seem to contradict scaling theory at all, both for the Hall plateau-insulator transition [18] and the transition between QHE plateaus [19,20].However, before making conclusions on a general failure of scaling theory it has to be considered that nearly all experiments do not measure the localization length ξ directly. Therefore an assumption about the functional form and exponents z and p of the effective length L eff (T, I, f ) has to be made.…”

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confidence: 99%

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confidence: 99%

Hopping Conductivity in the Quantum Hall Effect: Revival of Universal Scaling

2002

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We have measured the temperature dependence of the conductivity σxx of a two-dimensional electron system deep into the localized regime of the quantum Hall plateau transition. Using variable-range hopping theory we are able to extract directly the localization length ξ from this experiment. We use our results to study the scaling behavior of ξ as a function of the filling factor distance |δν| to the critical point of the transition. We find for all samples a power-law behavior ξ ∝ |δν| −γ with a universal scaling exponent γ = 2.3 as proposed theoretically.PACS numbers: 73.40. Hm, 71.23.An, 72.20.My, 71.30.+h The prominent feature of the quantum Hall effect (QHE) is the emergence of quantized plateaus in the Hall resistance of a two-dimensional electron system (2DES) reflecting the localization of states at the Fermi edge. A deeper understanding of this fascinating phenomenon is gained from regarding the transition region between adjacent QHE plateaus [1,2]. In this regime the dissipative transport is governed by the delocalized states in the vicinity of the Landau level center. The degree of localization is expressed by the localization length ξ denoting the typical extension of the electron wave function. For any sample with a finite size L theory predicts the conductivity tensor in the plateau transition to follow a scaling function f (L/ξ) with a diverging localization length ξ = |δν| −γ [3] where δν = ν − ν c denotes the filling factor distance to the critical point ν c of the transition. The critical exponent γ = 2.3 was predicted to be universal, its value determined numerically [4] and validated by variation of the sample size [5]. Experimentally the scaling of the conductivity near the critical point was verified with great success for different samples by temperature, current, and frequency dependent measurements of the transition width [6,7,8]. These new parameters introduce effective lengths, and L f ∝ f 1/z and thereby add additional exponents z and p. These effective lengths replace the physical sample size L in the scaling functions f (L/ξ). Recent experiments extended the focus to the transition from the quantum Hall state to the Hall insulator [9,10,11]. In these investigations striking similarities to the scaling behavior in the transition between different QH states were observed [12] hinting to the same universality class for both types of transitions [13,14].In spite of the great success of scaling theory in the QHE there are still some experiments not fitting into the picture of universality. Non-universal exponents were observed in the dependence of the transition width on temperature [15], current [16] and frequency [17]. Other experiments seem to contradict scaling theory at all, both for the Hall plateau-insulator transition [18] and the transition between QHE plateaus [19,20].However, before making conclusions on a general failure of scaling theory it has to be considered that nearly all experiments do not measure the localization length ξ directly. Therefore an assumption about the ...

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A new transport regime in the quantum Hall effect

Cited by 108 publications

References 19 publications

Quantum Fluctuations and the Closing of the Coulomb Gap in a Correlated Insulator

Quantum Fluctuations and the Closing of the Coulomb Gap in a Correlated Insulator

Quantum criticality at the Chern-to-normal insulator transition

Hopping Conductivity in the Quantum Hall Effect: Revival of Universal Scaling

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