Optimizing the Speed of a Josephson Junction with Dynamical Mean Field Theory

J. K. Freericks; B. K. Nikolić; P. Miller

doi:10.1142/S0217979202007379

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Optimizing the Speed of a Josephson Junction with Dynamical Mean Field Theory

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Optimizing the Speed of a Josephson Junction with Dynamical Mean Field Theory

J. K. Freericks, B. K. Nikolić and P. Miller

International journal of modern physics. B, Condensed matter physics, statistical physics, applied physics, Vol.16(4), pp.531-561

02/10/2002

DOI: https://doi.org/10.1142/S0217979202007379

Abstract

Condensed Matter Physics

Superconductivity

We review the application of dynamical mean-field theory to Josephson junctions and study how to maximize the characteristic voltage IcRn which determines the width of a rapid single flux quantum pulse, and thereby the operating speed in digital electronics. We study a wide class of junctions ranging from SNS, SCmS (where Cm stands for correlated metal), SINIS (where the insulating layer is formed from a screened dipole layer), and SNSNS structures. Our review is focused on a survey of the physical results; the formalism has been developed elsewhere.

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Title: Optimizing the Speed of a Josephson Junction with Dynamical Mean Field Theory
Creators: J. K. Freericks - Georgetown University
B. K. Nikolić - Georgetown University
P. Miller - Brandeis University, Department of Biology
Publication Details: International journal of modern physics. B, Condensed matter physics, statistical physics, applied physics, Vol.16(4), pp.531-561
Identifiers: 9924167583101921
Academic Unit: Benjamin and Mae Volen National Center for Complex Systems; Department of Biology; Interdepartmental Program in Neuroscience; Michtom School of Computer Science
Language: English
Resource Type: Journal article

Optimizing the Speed of a Josephson Junction with Dynamical Mean Field Theory

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