Principles of Superconductive Devices and Circuits |
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Page 139
... junction . The phase difference across the barrier is seen to be both temporally and spatially variable . It is used as the variable in a macroscopic ... Tunneling : The Josephson Relations In Section Josephson Tunnel Junctions.
... junction . The phase difference across the barrier is seen to be both temporally and spatially variable . It is used as the variable in a macroscopic ... Tunneling : The Josephson Relations In Section Josephson Tunnel Junctions.
Page 148
... Tunnel Junction In Section 4.02 we referred to the phase difference across the junction without explicit account being take of the fact that it can differ at different points in the junction . Here we shall derive an equation that ...
... Tunnel Junction In Section 4.02 we referred to the phase difference across the junction without explicit account being take of the fact that it can differ at different points in the junction . Here we shall derive an equation that ...
Page 174
... tunnel junction . The reason for this discrepancy is that the shunt conductance in a tunnel junction is actually far from constant . Reasonably ... junction is supplied 174 Chapter 5. The General Josephson Junction : Circuit Applications.
... tunnel junction . The reason for this discrepancy is that the shunt conductance in a tunnel junction is actually far from constant . Reasonably ... junction is supplied 174 Chapter 5. The General Josephson Junction : Circuit Applications.
Contents
Electrodynamics of Superconductors in Weak | 3 |
Microscopic Theory of the Equilibrium | 36 |
Josephson Tunnel Junctions | 139 |
Copyright | |
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Principles of Superconductive Devices and Circuits Theodore Van Duzer,Charles William Turner No preview available - 1999 |
Common terms and phrases
amplitude applied field applied flux array assumed average barrier behavior boundary calculated capacitance circulating current coherence length component conductivity conductor constant critical current critical field current density devices effect electrons equations equilibrium equivalent circuit excitation energy experimental Fermi energy Fermi gas Fermi surface Figure film flux density flux quantum footnote frequency gate Gibbs free energy Ginzburg-Landau given Helmholtz free energy I-V characteristic impedance inductance integral interaction interferometer Josephson effects Josephson junction lattice magnetic field magnetic flux magnitude maximum zero-voltage current Meissner normal metal obtained order parameter pair parallel penetration depth phonon Phys potential quasistatic region relation resistance result sample scattering semiconductor shown in Fig shows shunt signal specific heat SQUID SQUID loop supercon superconducting switching theory thermal thermodynamics thickness tion transition transport current tunnel junction tunneling current type II superconductors velocity voltage vortex vortices wave function zero Φο