Björn Sothmann, Stephan Weiss, Michele Governale, Jürgen König
Published 2014-04-03, updated 2014-12-01Version 2
The formation of electron pairs is a prerequisite of superconductivity. The fermionic nature of electrons yields four classes of superconducting correlations with definite symmetry in spin, space and time. Here, we suggest double quantum dots coupled to conventional s-wave superconductors in the presence of inhomogeneous magnetic fields as a model system exhibiting unconventional pairing. Due to their small number of degrees of freedom, tunable by gate voltages, quantum-dot systems provide an ideal tool to gain fundamental insight in unconventional pairing. We propose two detection schemes for unconventional superconductivity, based on either Josephson or Andreev spectroscopy.
Comments: 5 pages manuscript + 5 pages supplemental material
Journal: Phys. Rev. B 90, 220501(R) (2014)
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