Scanning Fourier Spectroscopy: A microwave analog study to image
  transmission paths in quantum dots

A. Kudrolli; A.P.S. de Moura; C. Dembowski; G. Salis; H. Alt; H.-J. Stöckmann; H.-J. Stöckmann; J. P. Bird; J. Stein; J.-Y. Marzin; J.P. Bird; M. Barth; M.A. Topinka; M.A. Topinka; M.T. Woodside; R. Akis; R.G. Nazmitdinov; S. Sridhar; T. Blomquist; T.M. Fromhold; T.M. Fromhold; U. Kuhl; U. Kuhl; U. Kuhl; Y.-H. Kim; Y.-H. Kim; Y.F. Chen

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Scanning Fourier Spectroscopy: A microwave analog study to image transmission paths in quantum dots

Authors: A. Kudrolli
A.P.S. de Moura
C. Dembowski
G. Salis
H. Alt
H.-J. Stöckmann
H.-J. Stöckmann
J. P. Bird
J. Stein
J.-Y. Marzin
J.P. Bird
M. Barth
M.A. Topinka
M.A. Topinka
M.T. Woodside
R. Akis
R.G. Nazmitdinov
S. Sridhar
T. Blomquist
T.M. Fromhold
T.M. Fromhold
U. Kuhl
U. Kuhl
U. Kuhl
Y.-H. Kim
Y.-H. Kim
Y.F. Chen
Publication date: 18 August 2003
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We use a microwave cavity to investigate the influence of a movable absorbing center on the wave function of an open quantum dot. Our study shows that the absorber acts as a position-selective probe, which may be used to suppress those wave function states that exhibit an enhancement of their probability density near the region where the impurity is located. For an experimental probe of this wave function selection, we develop a technique that we refer to as scanning Fourier spectroscopy, which allows us to identify, and map out, the structure of the classical trajectories that are important for transmission through the cavity.Comment: 4 pages, 5 figure

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