Yoichi Tanaka, Norio Kawakami, Akira Oguri
Published 2007-01-24, updated 2008-07-16Version 4
We study transport through a quantum dot coupled to normal and superconducting leads using the numerical renormalization group method. We show that the low-energy properties of the system are described by the local Fermi liquid theory despite of the superconducting correlations penetrated into the dot due to a proximity effect. We calculate the linear conductance due to the Andreev reflection in the presence of the Coulomb interaction. It is demonstrated that the maximum structure appearing in the conductance clearly characterizes a crossover between two distinct spin-singlet ground states, i.e. the superconducting singlet state and the Kondo singlet state. It is further elucidated that the gate-voltage dependence of the conductance shows different behavior in the superconducting singlet region from that in the Kondo singlet region.
Comments: 10 pages, 6 figures; a typo in eq. (B.5) corrected, which does not affect any other results of the paper
Journal: J. Phys. Soc. Jpn. 76, 074701 (2007)
Changing the Electronic Spectrum of a Quantum Dot by Adding Electrons
Time-Resolved Detection of Individual Electrons in a Quantum Dot
Charge Fluctuations in a Quantum Dot with a Dissipative Environment
