R. Danneau scite author profile

We report a study of one-dimensional subband splitting in a bilayer graphene quantum point contact in which quantized conductance in steps of 4 e 2 /h is clearly defined down to the lowest subband. While our source-drain bias spectroscopy measurements reveal an unconventional confinement, we observe a full lifting of the valley degeneracy at high magnetic fields perpendicular to the bilayer graphene plane for the first two lowest subbands where confinement and Coulomb interactions are the strongest and a peculiar merging/mixing of K and K valleys from two non-adjacent subbands with indices (N, N + 2) which are well described by our semi-phenomenological model. arXiv:1809.02458v2 [cond-mat.mes-hall]

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Ballistic transport in induced one-dimensional hole systems

Klochan

Clarke

Danneau

et al. 2006

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We have fabricated and studied a ballistic one-dimensional p-type quantum wire using an undoped AlGaAs/GaAs heterostructure. The absence of modulation doping eliminates remote ionized impurity scattering and allows high mobilities to be achieved over a wide range of hole densities, and in particular, at very low densities where carrier-carrier interactions are strongest. The device exhibits clear quantized conductance plateaus with highly stable gate characteristics. These devices provide opportunities for studying spin-orbit coupling and interaction effects in mesoscopic hole systems in the strong interaction regime where r s > 10.

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Individual Domain Wall Resistance in Submicron Ferromagnetic Structures

et al. 2002

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The resistance generated by individual domain walls is measured in a FePd nanostructure. Combining transport and magnetic imaging measurements, the intrinsic domain wall resistance is quantified. It is found positive and of a magnitude consistent with that predicted by models based on spin scattering effects within the walls. This magnetoresistance at a nanometer scale allows a direct counting of the number of walls inside the nanostructure. The effect is then used to measure changes in the magnetic configuration of submicron stripes under application of a magnetic field.

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R. Danneau

Shot Noise in Ballistic Graphene

Zeeman Splitting in Ballistic Hole Quantum Wires

Valley Subband Splitting in Bilayer Graphene Quantum Point Contacts

Ballistic transport in induced one-dimensional hole systems

Individual Domain Wall Resistance in Submicron Ferromagnetic Structures

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