Resonant transmission through an open quantum dot

A.T. Johnson; B. Su; B.J. van Wees; C. G. Smith; C. H. W. Barnes; C. J. B. Ford; C.-T. Liang; C.G. Darwin; C.G. Smith; C.J.B. Ford; D. A. Ritchie; D.A. Wharam; D.R. Mace; E. Tekman; I. M. Castleton; J. E. F. Frost; J. Weis; J. Weis; J.G. Williamson; J.H. Davies; J.H.F. Scott-Thomas; J.K. Jain; J.T. Nicholls; L.I. Glazman; M. Pepper; M. Pepper; N.K. Patel; N.W. Ashcroft; P.L. McEuen; P.L. McEuen; R.C. Ashoori; R.J. Nicholas; R.J. Stroh; U. Meirav; Y. Meir; Y. Meir

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Resonant transmission through an open quantum dot

Authors: A.T. Johnson
B. Su
B.J. van Wees
C. G. Smith
C. H. W. Barnes
C. J. B. Ford
C.-T. Liang
C.G. Darwin
C.G. Smith
C.J.B. Ford
D. A. Ritchie
D.A. Wharam
D.R. Mace
E. Tekman
I. M. Castleton
J. E. F. Frost
J. Weis
J. Weis
J.G. Williamson
J.H. Davies
J.H.F. Scott-Thomas
J.K. Jain
J.T. Nicholls
L.I. Glazman
M. Pepper
M. Pepper
N.K. Patel
N.W. Ashcroft
P.L. McEuen
P.L. McEuen
R.C. Ashoori
R.J. Nicholas
R.J. Stroh
U. Meirav
Y. Meir
Y. Meir
Publication date: 9 January 1997
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We have measured the low-temperature transport properties of a quantum dot formed in a one-dimensional channel. In zero magnetic field this device shows quantized ballistic conductance plateaus with resonant tunneling peaks in each transition region between plateaus. Studies of this structure as a function of applied perpendicular magnetic field and source-drain bias indicate that resonant structure deriving from tightly bound states is split by Coulomb charging at zero magnetic field.Comment: To be published in Phys. Rev. B (1997). 8 LaTex pages with 5 figure

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