Mesoscopic Josephson effect in graphene disk at magnetic field

Abstract

Unlike for tunneling Josephson junctions, for which the current-phase relation is given by the sine function, with the critical current (Ic) and normal-state resistance (RN) following the relation IcRN=(π/2)\,0/e (where 0 is the superconducting gap and electron charge is -e), mesoscopic Josephson junctions show more complex current-phase relations, with the skewness S>0, what is related to the presence -- in case the leads are in the normal state -- of transmission probabilities taking the values comparable to 1. Here, we show that these features also appear for a superconductor-graphene-superconductor (S-g-S) junction in the disk-shaped (Corbino) geometry, when the magnetic field is adjusted such that Ic→0 and RN→∞. In such a case, the product IcRN≈1.85\,0/e, and the skewness S≈0.14. The results obtained from quantum-mechanical mode-matching analysis for the Dirac-Bogoliubov-De-Gennes equation are compared with simpler model assuming incoherent scattering between two circular interfaces separating the sample and the leads.