Transmission through multiply-connected wire systems

D. Kowal; U. Sivan; O. Entin-Wohlman; Y. Imry

doi:10.1103/PhysRevB.42.9009

Transmission through multiply-connected wire systems

D. Kowal, U. Sivan, O. Entin-Wohlman, Y. Imry

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

92 Scopus citations

Abstract

Employing a Landauer-type picture, the chemical potential at a certain site in a multiply-connected wire system is expressed in terms of the transmission amplitudes between this site and the external electron reservoirs. The result is applied to geometries involving rings containing magnetic flux, in order to derive nonlocal quantum interference effects in the conductance. As an example, h/e oscillations are obtained in the conductance of a wire with a dangling ring and in the conductance of a resistor in series with a ring. The general form of the scattering matrix of a three-terminal fork governing the transmission of a ring is found and exemplified by an explicit calculation within the tight-binding model. This example shows that, in general, the scattering matrix is not real (as assumed in previous studies), but that the qualitative results are not sensitive to the detailed form of the matrix.

Original language	English
Pages (from-to)	9009-9018
Number of pages	10
Journal	Physical Review B-Condensed Matter
Volume	42
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevB.42.9009
State	Published - 1990

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abstract = "Employing a Landauer-type picture, the chemical potential at a certain site in a multiply-connected wire system is expressed in terms of the transmission amplitudes between this site and the external electron reservoirs. The result is applied to geometries involving rings containing magnetic flux, in order to derive nonlocal quantum interference effects in the conductance. As an example, h/e oscillations are obtained in the conductance of a wire with a dangling ring and in the conductance of a resistor in series with a ring. The general form of the scattering matrix of a three-terminal fork governing the transmission of a ring is found and exemplified by an explicit calculation within the tight-binding model. This example shows that, in general, the scattering matrix is not real (as assumed in previous studies), but that the qualitative results are not sensitive to the detailed form of the matrix.",

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AU - Entin-Wohlman, O.

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AB - Employing a Landauer-type picture, the chemical potential at a certain site in a multiply-connected wire system is expressed in terms of the transmission amplitudes between this site and the external electron reservoirs. The result is applied to geometries involving rings containing magnetic flux, in order to derive nonlocal quantum interference effects in the conductance. As an example, h/e oscillations are obtained in the conductance of a wire with a dangling ring and in the conductance of a resistor in series with a ring. The general form of the scattering matrix of a three-terminal fork governing the transmission of a ring is found and exemplified by an explicit calculation within the tight-binding model. This example shows that, in general, the scattering matrix is not real (as assumed in previous studies), but that the qualitative results are not sensitive to the detailed form of the matrix.

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Transmission through multiply-connected wire systems

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