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Perfect crossed Andreev reflection in the proximitized graphene/superconductor/proximitized graphene junctions

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arxiv 2310.17301 v1 pith:DVJDJB5O submitted 2023-10-26 cond-mat.supr-con cond-mat.mes-hall

Perfect crossed Andreev reflection in the proximitized graphene/superconductor/proximitized graphene junctions

classification cond-mat.supr-con cond-mat.mes-hall
keywords andreevgraphenereflectioncrossedproximitizedspin-orbitcouplingelectrons
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We study the crossed Andreev reflection and the nonlocal transport in the proximitized graphene/supercondcutor/proximitized graphene junctions with the pseudospin staggered potential and the intrinsic spin-orbit coupling. The crossed Andreev reflection with the local Andreev reflection and the elastic cotunneling being completely eliminated can be realized for the electrons with the specific spin-valley index when the intrinsic spin-orbit couplings in the left graphene and the right graphene possess the opposite sign. The perfect crossed Andreev reflection with its probability equal to $100\%$ can be obtained in the space consisting of the incident angle and the energy of the electrons. The crossed conductance and its oscillation with the superconductor length are also investigated. The energy ranges for the crossed Andreev reflection without the local Andreev reflection and the elastic cotunneling are clarified for the different magnitudes of the pseudospin potential and the spin-orbit coupling. The spin-valley index of the electrons responsible for the perfect crossed Andreev reflection can be switched by changing the sign of the intrinsic spin-orbit coupling or exchanging the biases applied on the left graphene and the right graphene. Our results are helpful for designing the flexible and high-efficiency Cooper pair splitter based on the spin-valley degree of freedom.

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