Tunneling conductance of graphene ferromagnet-insulator-superconductor junctions

Abstract

We study the transport properties of a graphene ferromagnet-insulator superconductor (FIS) junction within the Blonder-Tinkham-Klapwijk formalism by solving spin-polarized Dirac-Bogoliubov-de-Gennes equation. We find that the retro and specular Andreev reflections in the graphene FIS junction are drastically modified in the presence of exchange interaction and that the spin-polarization (PT) of tunneling current can be tuned from the positive to negative value by bias voltage (V). In the thin-barrier limit, the conductance G of a graphene FIS junction oscillates as a function of barrier strength . Both the amplitude and phase of the conductance oscillation varies with the exchange energy Eex. For Eex<EF (Fermi energy), the amplitude of oscillation decreases with Eex. For Eexc>Eex>EF, the amplitude of oscillation increases with Eex, where Eexc=2EF+U0 (U0 is the applied electrostatic potential on the superconducting segment of the junction). For Eex > Eexc, the amplitude of oscillation decreases with Eex again. Interestingly, a universal phase difference of π/2 in exists between the G- curves for Eex>EF and Eex<EF. Finally, we find that the transitions between retro and specular Andreev reflections occur at eV=|EF-Eex| and eV=Eex+EF, and hence the singular behavior of the conductance near these bias voltages results from the difference in transport properties between specular and retro Andreev reflections.