Contact superconductivity in In–PbTe junctions

Abstract

We report on electron transport studies on superconductor/semiconductor hybrid structures of indium and n-type PbTe quantum wells embedded between Pb0.92Eu0.08Te barriers. In/PbTe contacts form by spontaneous alloying, which occurs already at room temperature. The alloyed phase penetrates deeply into the semiconductor and forms metallic contacts even in the presence of depletion layers at the semiconductor’s surface. Although the detailed structure of this phase is unknown, we observe that it exhibits a superconducting transition at temperatures below 7 K. This causes such substantial reduction in the contact resistances that they even become comparable to those predicted for ideal superconductor-normal conductor contacts. Our findings suggest that the new superconducting phase is result of Josephson coupling arising between tiny superconducting precipitates randomly distributed in the interface region. In analogy to the granular superconducting systems, the coupling would lead to the occurrence of the global superconductivity only when the Coulomb charging energies of the precipitates are sufficiently small. This condition is exceptionally well fulfilled in PbTe because of a huge static dielectric constant of this material, ε>1000.