Nonequilibrium transport via spin-induced sub-gap states in superconductor/quantum dot/normal metal cotunnel junctions

Verena Koerting; Brian Møller Andersen; Karsten Flensberg; Jens Paaske

doi:10.1103/PhysRevB.82.245108

Nonequilibrium transport via spin-induced sub-gap states in superconductor/quantum dot/normal metal cotunnel junctions

Verena Koerting, Brian Møller Andersen, Karsten Flensberg, Jens Paaske

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Abstract

We study low-temperature transport through a Coulomb blockaded quantum dot (QD) contacted by a normal (N) and a superconducting (S) electrode. Within an effective cotunneling model the conduction electron self-energy is calculated to leading order in the cotunneling amplitudes and subsequently resummed to obtain the nonequilibrium T matrix, from which we obtain the nonlinear cotunneling conductance. For even-occupied dots the system can be conceived as an effective S/N-cotunnel junction with subgap transport mediated by Andreev reflections. The net spin of an odd-occupied dot, however, leads to the formation of subgap resonances inside the superconducting gap which give rise to a characteristic peak-dip structure in the differential conductance, as observed in recent experiments.

Original language	English
Journal	Physical Review B Condensed Matter
Volume	82
Issue number	24
Pages (from-to)	245108
Number of pages	12
ISSN	0163-1829
DOIs	https://doi.org/10.1103/PhysRevB.82.245108
Publication status	Published - 8 Dec 2010

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title = "Nonequilibrium transport via spin-induced sub-gap states in superconductor/quantum dot/normal metal cotunnel junctions",

abstract = "We study low-temperature transport through a Coulomb blockaded quantum dot (QD) contacted by a normal (N) and a superconducting (S) electrode. Within an effective cotunneling model the conduction electron self-energy is calculated to leading order in the cotunneling amplitudes and subsequently resummed to obtain the nonequilibrium T matrix, from which we obtain the nonlinear cotunneling conductance. For even-occupied dots the system can be conceived as an effective S/N-cotunnel junction with subgap transport mediated by Andreev reflections. The net spin of an odd-occupied dot, however, leads to the formation of subgap resonances inside the superconducting gap which give rise to a characteristic peak-dip structure in the differential conductance, as observed in recent experiments.",

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T1 - Nonequilibrium transport via spin-induced sub-gap states in superconductor/quantum dot/normal metal cotunnel junctions

AU - Koerting, Verena

AU - Andersen, Brian Møller

AU - Flensberg, Karsten

AU - Paaske, Jens

PY - 2010/12/8

Y1 - 2010/12/8

N2 - We study low-temperature transport through a Coulomb blockaded quantum dot (QD) contacted by a normal (N) and a superconducting (S) electrode. Within an effective cotunneling model the conduction electron self-energy is calculated to leading order in the cotunneling amplitudes and subsequently resummed to obtain the nonequilibrium T matrix, from which we obtain the nonlinear cotunneling conductance. For even-occupied dots the system can be conceived as an effective S/N-cotunnel junction with subgap transport mediated by Andreev reflections. The net spin of an odd-occupied dot, however, leads to the formation of subgap resonances inside the superconducting gap which give rise to a characteristic peak-dip structure in the differential conductance, as observed in recent experiments.

AB - We study low-temperature transport through a Coulomb blockaded quantum dot (QD) contacted by a normal (N) and a superconducting (S) electrode. Within an effective cotunneling model the conduction electron self-energy is calculated to leading order in the cotunneling amplitudes and subsequently resummed to obtain the nonequilibrium T matrix, from which we obtain the nonlinear cotunneling conductance. For even-occupied dots the system can be conceived as an effective S/N-cotunnel junction with subgap transport mediated by Andreev reflections. The net spin of an odd-occupied dot, however, leads to the formation of subgap resonances inside the superconducting gap which give rise to a characteristic peak-dip structure in the differential conductance, as observed in recent experiments.

U2 - 10.1103/PhysRevB.82.245108

DO - 10.1103/PhysRevB.82.245108

M3 - Journal article

SN - 2469-9950

VL - 82

SP - 245108

JO - Physical Review B

JF - Physical Review B

IS - 24

ER -

Nonequilibrium transport via spin-induced sub-gap states in superconductor/quantum dot/normal metal cotunnel junctions

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