1. Tunable supercurrent in superconductor/normal metal/superconductor Josephson junctions
- Author
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Jochem J. A. Baselmans, A. F. Morpurgo, T. M. Klapwijk, B. J. van Wees, Faculty of Science and Engineering, Zernike Institute for Advanced Materials, Fysica van Nano Devices, Oppervlakken en Dunne Lagen, and Fysische Technologie
- Subjects
Josephson effect ,SYMMETRY ,FLOW ,Quantum phases ,electron-electron interactions ,Pi Josephson junction ,Tunnel effect ,Quantum mechanics ,Condensed Matter::Superconductivity ,General Materials Science ,Electrical and Electronic Engineering ,TEMPERATURE ,Superconductivity ,Physics ,Condensed Matter::Quantum Gases ,mesoscopic superconductivity ,Condensed matter physics ,business.industry ,Supercurrent ,Condensed Matter Physics ,Condensed Matter::Mesoscopic Systems and Quantum Hall Effect ,STATE ,Semiconductor ,superconducting transistors ,Superconducting tunnel junction ,ddc:500 ,business - Abstract
When two superconductors are connected by a weak link a supercurrent flows determined by the difference in the macroscopic quantum phases of the superconductors. Originally, this phenomenon was discovered by Josephson [1] for the case of a weak link formed by a thin tunnel barrier. The supercurrent I is related to the phase difference ’ through the Josephson current‐phase relation, I D Ic sin’, with Ic, the critical current, depending on the properties of the weak link. A similar relation holds for weak links consisting of a normal metal, a semiconductor or a constriction [2]. In all cases, the phase difference ’ D 0 when no supercurrent flows through the junction, and ’ increases monotonically with increasing supercurrent until the critical current is reached. Using nanolithography techniques we have succeeded in making and studying a Josephson junction with a normal metal weak link, in which we have direct access to the microscopic current-carrying states inside the link. We find that the fundamental Josephson relation can be changed from I D Ic sin’ to I D Ic sin.’C/ , i.e. to a -junction, by suitably controlling the energy distribution of the current-carrying states in the normal metal. This fundamental change in the way these Josephson junctions behave has potential implications for their use in superconducting electronics as well as (quantum) logic circuits based on superconductors. c 1999 Academic Press
- Published
- 1999