Superconductivity in quantum-dot superlattices composed of quantum wire
  networks

A. Mielke; A. Taguchi; C. Albrecht; C.-H. Pao; D.J. Scalapino; E. Dagotto; G. Schedelbeck; G.M. Eliashberg; H. Namatsu; Hideaki Takayanagi; Hiroyuki Tamura; I.-H. Lee; J.P. Perdew; K. Kumakura; K. Kuroki; K. Kuroki; K. Shiraishi; Kazuhiko Kuroki; Kenji Shiraishi; M. Koskinen; N.E. Bickers; N.E. Bickers; P. Monthoux; R.C. Ashoori; Ryotaro Arita; S. Grabowski; S. Tarucha; S.R. White; T. Dahm; Takashi Kimura

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Superconductivity in quantum-dot superlattices composed of quantum wire networks

Authors: A. Mielke
A. Taguchi
C. Albrecht
C.-H. Pao
D.J. Scalapino
E. Dagotto
G. Schedelbeck
G.M. Eliashberg
H. Namatsu
Hideaki Takayanagi
Hiroyuki Tamura
I.-H. Lee
J.P. Perdew
K. Kumakura
K. Kuroki
K. Kuroki
K. Shiraishi
Kazuhiko Kuroki
Kenji Shiraishi
M. Koskinen
N.E. Bickers
N.E. Bickers
P. Monthoux
R.C. Ashoori
Ryotaro Arita
S. Grabowski
S. Tarucha
S.R. White
T. Dahm
Takashi Kimura
Publication date: 10 April 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Based on calculations using the local density approximation, we propose quantum wire networks with square and plaquette type lattice structures that form quantum dot superlattices. These artificial structures are well described by the Hubbard model. Numerical analysis reveals a superconducting ground state with transition temperatures

T_c

of up to 90 mK for the plaquette, which is more than double the value of 40 mK for the square lattice type and is sufficiently high to allow for the experimental observation of superconductivity.Comment: 10 pages, 4 figure

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