Josephson current in a graphene SG/ferromagnetic barrier/SG junction

The Josephson current passing through a SG1/FB/SG2graphene junction, where SG and FBare those parts of a graphene layer which are induced into the superconducting state and into the ferromagnetic state, respectively, and where the small thickness of the FBlayer L is studied. The ferromagnetic barrie...

Full description

Saved in:
Bibliographic Details
Main Authors: Bumned Soodchomshom, I. Ming Tang, Rassmidara Hoonsawat
Other Authors: Mahidol University
Format: Article
Published: 2018
Subjects:
Online Access:https://repository.li.mahidol.ac.th/handle/123456789/19180
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Mahidol University
Description
Summary:The Josephson current passing through a SG1/FB/SG2graphene junction, where SG and FBare those parts of a graphene layer which are induced into the superconducting state and into the ferromagnetic state, respectively, and where the small thickness of the FBlayer L is studied. The ferromagnetic barrier strength is taken to be given by χH∼ HL/ℏvF, where H is the strength of the exchange energy and vF∼ 106m/s is the Fermi velocity of quasiparticles. The eigenstates of the relativistic quasiparticles in the graphene are taken to be the solutions of the Dirac Bogoliubov-de Gennes equations. It is found that the energy levels of the Andreev bound states for the Weyl-Dirac particles in the SG1/FB/SG2junction are independent of the direction of the spins and that they depend on the strength of ferromagnetic barrier potential. The critical supercurrent is seen to vary in an oscillatory (periodic) manner as χHis varied. The oscillatory behavior of the critical supercurrent carried by the Cooper pairs formed by massless the Weyl-Dirac particles is different from the behavior of the supercurrent carried by the Cooper pairs formed by non-relativistic particles in a conventional SC/FI/SC (FI being a ferromagnetic insulator) junction. In those types of junctions, the supercurrent does not exhibit a similar oscillatory dependence. © 2008 Elsevier B.V. All rights reserved.