11,635 research outputs found

    Coulomb Oscillations in Antidots in the Integer and Fractional Quantum Hall Regimes

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    We report measurements of resistance oscillations in micron-scale antidots in both the integer and fractional quantum Hall regimes. In the integer regime, we conclude that oscillations are of the Coulomb type from the scaling of magnetic field period with the number of edges bound to the antidot. Based on both gate-voltage and field periods, we find at filling factor {\nu} = 2 a tunneling charge of e and two charged edges. Generalizing this picture to the fractional regime, we find (again, based on field and gate-voltage periods) at {\nu} = 2/3 a tunneling charge of (2/3)e and a single charged edge.Comment: related papers at http://marcuslab.harvard.ed

    Zero-Bias Anomalies in Narrow Tunnel Junctions in the Quantum Hall Regime

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    We report on the study of cleaved-edge-overgrown line junctions with a serendipitously created narrow opening in an otherwise thin, precise line barrier. Two sets of zero-bias anomalies are observed with an enhanced conductance for filling factors ν>1\nu > 1 and a strongly suppressed conductance for ν<1\nu < 1. A transition between the two behaviors is found near ν≈1\nu \approx 1. The zero-bias anomaly (ZBA) line shapes find explanation in Luttinger liquid models of tunneling between quantum Hall edge states. The ZBA for ν<1\nu < 1 occurs from strong backscattering induced by suppression of quasiparticle tunneling between the edge channels for the n=0n = 0 Landau levels. The ZBA for ν>1\nu > 1 arises from weak tunneling of quasiparticles between the n=1n = 1 edge channels.Comment: version with edits for clarit

    Cascade of Quantum Phase Transitions in Tunnel-Coupled Edge States

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    We report on the cascade of quantum phase transitions exhibited by tunnel-coupled edge states across a quantum Hall line junction. We identify a series of quantum critical points between successive strong and weak tunneling regimes in the zero-bias conductance. Scaling analysis shows that the conductance near the critical magnetic fields BcB_{c} is a function of a single scaling argument ∣B−Bc∣T−κ|B-B_{c}|T^{-\kappa}, where the exponent κ=0.42\kappa = 0.42. This puzzling resemblance to a quantum Hall-insulator transition points to importance of interedge correlation between the coupled edge states.Comment: 4 pages, 3 figure
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