Scanning gate imaging in confined geometries

R. Steinacher; A. A. Kozikov; C. Rössler; C. Reichl; W. Wegscheider; K. Ensslin; T. Ihn

doi:10.1103/PhysRevB.93.085303

Scanning gate imaging in confined geometries

R. Steinacher, A. A. Kozikov, C. Rössler, C. Reichl, W. Wegscheider, K. Ensslin, T. Ihn

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Abstract

This article reports on tunable electron backscattering investigated with the biased tip of a scanning force microscope. Using a channel defined by a pair of Schottky gates, the branched electron flow of ballistic electrons injected from a quantum point contact is guided by potentials of a tunable height well below the Fermi energy. The transition from injection into an open two-dimensional electron gas to a strongly confined channel exhibits three experimentally distinct regimes: one in which branches spread unrestrictedly, one in which branches are confined but the background conductance is affected very little, and one where the branches have disappeared and the conductance is strongly modified. Classical trajectory-based simulations explain these regimes at the microscopic level. These experiments allow us to understand under which conditions branches observed in scanning gate experiments do or do not reflect the flow of electrons.

Original language	English
Article number	085303
Journal	Physical Review B
Volume	93
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevB.93.085303
Publication status	Published - 2 Feb 2016

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PhysRevB.93.085303Final published version, 4.09 MB

https://arxiv.org/abs/1602.03372

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title = "Scanning gate imaging in confined geometries",

abstract = "This article reports on tunable electron backscattering investigated with the biased tip of a scanning force microscope. Using a channel defined by a pair of Schottky gates, the branched electron flow of ballistic electrons injected from a quantum point contact is guided by potentials of a tunable height well below the Fermi energy. The transition from injection into an open two-dimensional electron gas to a strongly confined channel exhibits three experimentally distinct regimes: one in which branches spread unrestrictedly, one in which branches are confined but the background conductance is affected very little, and one where the branches have disappeared and the conductance is strongly modified. Classical trajectory-based simulations explain these regimes at the microscopic level. These experiments allow us to understand under which conditions branches observed in scanning gate experiments do or do not reflect the flow of electrons.",

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AU - Steinacher, R.

AU - Kozikov, A. A.

AU - Rössler, C.

AU - Reichl, C.

AU - Wegscheider, W.

AU - Ensslin, K.

AU - Ihn, T.

PY - 2016/2/2

Y1 - 2016/2/2

N2 - This article reports on tunable electron backscattering investigated with the biased tip of a scanning force microscope. Using a channel defined by a pair of Schottky gates, the branched electron flow of ballistic electrons injected from a quantum point contact is guided by potentials of a tunable height well below the Fermi energy. The transition from injection into an open two-dimensional electron gas to a strongly confined channel exhibits three experimentally distinct regimes: one in which branches spread unrestrictedly, one in which branches are confined but the background conductance is affected very little, and one where the branches have disappeared and the conductance is strongly modified. Classical trajectory-based simulations explain these regimes at the microscopic level. These experiments allow us to understand under which conditions branches observed in scanning gate experiments do or do not reflect the flow of electrons.

AB - This article reports on tunable electron backscattering investigated with the biased tip of a scanning force microscope. Using a channel defined by a pair of Schottky gates, the branched electron flow of ballistic electrons injected from a quantum point contact is guided by potentials of a tunable height well below the Fermi energy. The transition from injection into an open two-dimensional electron gas to a strongly confined channel exhibits three experimentally distinct regimes: one in which branches spread unrestrictedly, one in which branches are confined but the background conductance is affected very little, and one where the branches have disappeared and the conductance is strongly modified. Classical trajectory-based simulations explain these regimes at the microscopic level. These experiments allow us to understand under which conditions branches observed in scanning gate experiments do or do not reflect the flow of electrons.

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DO - 10.1103/PhysRevB.93.085303

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VL - 93

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Scanning gate imaging in confined geometries

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