Microscopic Theory of Josephson Mesoscopic Constrictions

A. Furusaki; A. Katalsky; A. Levy Yeyati; A. Levy Yeyati; A. Martín Rodero; A. Martín-Rodero; C. Nguyen; C.J. Muller; C.W.J. Beenakker; C.W.J. Beenakker; F. J. García-Vidal; G.B. Arnold; G.E. Blonder; J. Ferrer; J.L. D'Amato; K.K. Likharev; K.K. Likharev; L. Kramer; L.G. Aslamazov; L.V. Keldysh; M. Buttiker; N. Agrait; N. Agrait; O. Kulik; O. Kulik; O. Kulik; P. L. Pernas; V. Ambegaokar; V. Ambegaokar; Y. Nambu

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Microscopic Theory of Josephson Mesoscopic Constrictions

Authors: A. Furusaki
A. Katalsky
A. Levy Yeyati
A. Levy Yeyati
A. Martín Rodero
A. Martín-Rodero
C. Nguyen
C.J. Muller
C.W.J. Beenakker
C.W.J. Beenakker
F. J. García-Vidal
G.B. Arnold
G.E. Blonder
J. Ferrer
J.L. D'Amato
K.K. Likharev
K.K. Likharev
L. Kramer
L.G. Aslamazov
L.V. Keldysh
M. Buttiker
N. Agrait
N. Agrait
O. Kulik
O. Kulik
O. Kulik
P. L. Pernas
V. Ambegaokar
V. Ambegaokar
Y. Nambu
Publication date: 20 December 1993
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We present a microscopic theory for the d.c. Josephson effect in model mesoscopic constrictions. Our method is based on a non-equilibrium Green function formalism which allows for a self-consistent determination of the order parameter profile along the constriction. The various regimes defined by the different length scales (Fermi wavelength

\lambda_F

, coherence length

\xi_0

and constriction length

L_C

) can be analyzed, including the case where all these lengths are comparable. For the case

\lambda_F \tilde{<} (L_C,\xi_0)

phase oscillations with spatial period

\lambda_F/2

can be observed. In the case of

L_C>\xi_0

solutions with a phase-slip center inside the constriction can be found, in agreement with previous phenomenological theories.Comment: 4 pages (RevTex 3.0), 3 postscript figures available upon request, 312456-C

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