Studies of spin-orbit scattering in noble-metal nanoparticles using
  energy level tunneling spectroscopy

A. Y. Zyuzin; C. W. J. Beenakker; D. C. Ralph; D. C. Ralph; D. Davidović; D. G. Salinas; G. Bergmann; J. Fabian; J. R. Petta; J. Sone; K. A. Matveev; K. S. Ralls; M. L. Mehta; N. W. Ashcroft; P. W. Brouwer; R. J. Elliott; S. Datta; W. P. Halperin; Y. Yafet

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Studies of spin-orbit scattering in noble-metal nanoparticles using energy level tunneling spectroscopy

Authors: A. Y. Zyuzin
C. W. J. Beenakker
D. C. Ralph
D. C. Ralph
D. Davidović
D. G. Salinas
G. Bergmann
J. Fabian
J. R. Petta
J. Sone
K. A. Matveev
K. S. Ralls
M. L. Mehta
N. W. Ashcroft
P. W. Brouwer
R. J. Elliott
S. Datta
W. P. Halperin
Y. Yafet
Publication date: 21 June 2001
Publisher: 'American Physical Society (APS)'
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Abstract

The effects of spin-orbit scattering on discrete electronic energy levels are studied in copper, silver, and gold nanoparticles. Level-to-level fluctuations of the effective

g

-factor for Zeeman splitting are characterized, and the statistics are found to be well-described by random matrix theory predictions. The strength of spin-orbit scattering increases with atomic number and also varies between nanoparticles made of the same metal. The spin-orbit scattering rates in the nanoparticles are in order-of-magnitude agreement with bulk measurements on disordered samples.Comment: 4 pages, 3 figures, 1 in colo

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