📝 SummarXiv

Abstract

The Hamiltonian J of the Josephson junction is introduced as a self-adjoint operator on l2 tensor l2. It is shown that J can also be realized as a self-adjoint operator HS1 on L2(S1) tensor L2(S1), from which a Mathieu operator given by "-d^2/d{\theta}^2 - 2{\alpha} cos {\theta}" is derived. A fiber decomposition of HS1 with respect to the total particle number is established, and the action on each fiber is analyzed. In the presence of a magnetic field, a phase shift defines the magnetic Josephson junction Hamiltonian HS1({\Phi}) and the Josephson current IS1({\Phi}). For a constant magnetic field inducing a local phase shift {\Phi}(x), the corresponding local current IS1({\Phi}(x)) is computed, and it is proved that the Fraunhofer pattern arises naturally.