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Closing the proximity gap in a metallic Josephson junction between three superconductors

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arxiv 1508.03289 v2 pith:HYWVCXSL submitted 2015-08-13 cond-mat.mes-hall

Closing the proximity gap in a metallic Josephson junction between three superconductors

classification cond-mat.mes-hall
keywords junctionstatesdensityareametalliccalculateclosingdecoherence
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We describe the proximity effect in a short disordered metallic junction between three superconducting leads. Andreev bound states in the multi-terminal junction may cross the Fermi level. We reveal that for a quasi-continuous metallic density of states, crossings at the Fermi level manifest as closing of the proximity-induced gap. We calculate the local density of states for a wide range of transport parameters using quantum circuit theory. The gap closes inside an area of the space spanned by the superconducting phase differences. We derive an approximate analytic expression for the boundary of the area and compare it to the full numerical solution. The size of the area increases with the transparency of the junction and is sensitive to asymmetry. The finite density of states at zero energy is unaffected by electron-hole decoherence present in the junction, although decoherence is important at higher energies. Our predictions can be tested using tunneling transport spectroscopy. To encourage experiments, we calculate the current-voltage characteristic in a typical measurement setup. We show how the structure of the local density of states can be mapped out from the measurement.

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