Semiclassical Theory of Coulomb Blockade Peak Heights in Chaotic Quantum
  Dots

A.M. Chang; C. Jarzynski; C.E. Shannon; C.E. Shannon; C.W.J. Beenakker; D. Saraga; D. Weiss; D.R. Stewart; E.B. Bogomolny; E.E. Narimanov; E.E. Narimanov; E.E. Narimanov; E.J. Heller; Evgenii E. Narimanov; G. Hackenbroich; G. Hackenbroich; H. Grabert; H.U. Baranger; Harold U. Baranger; J. Bardeen; J.A. Folk; J.B. Delos; K. Richter; L. Kaplan; L. Kaplan; L. Kaplan; M. Brack; M. Brack; M. Gutzwiller; M. Srednicki; M. Srednicki; M. Stopa; M. Stopa; M.A. Topinka; M.V. Berry; M.W. Beims; Nicholas R. Cerruti; P.W. Brouwer; P.W. O’Connor; R.A. Jalabert; R.O. Vallejos; S. Hortikar; S.M. Cronenwett; S.R. Patel; Steven Tomsovic; T. Szeredi; T.S. Monteiro; V.N. Prigodin; V.N. Prigodin; V.N. Prigodin; V.N. Prigodin; Y. Alhassid; Y. Alhassid; Y. Alhassid

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Semiclassical Theory of Coulomb Blockade Peak Heights in Chaotic Quantum Dots

Abstract

We develop a semiclassical theory of Coulomb blockade peak heights in chaotic quantum dots. Using Berry's conjecture, we calculate the peak height distributions and the correlation functions. We demonstrate that the corrections to the corresponding results of the standard statistical theory are non-universal and can be expressed in terms of the classical periodic orbits of the dot that are well coupled to the leads. The main effect is an oscillatory dependence of the peak heights on any parameter which is varied; it is substantial for both symmetric and asymmetric lead placement. Surprisingly, these dynamical effects do not influence the full distribution of peak heights, but are clearly seen in the correlation function or power spectrum. For non-zero temperature, the correlation function obtained theoretically is in good agreement with that measured experimentally.Comment: 5 color eps figure

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info:doi/10.1103%2Fphysrevb.64...

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