Universal Pulse Shape Scaling Function and Exponents: A Critical Test
  for Avalanche Models applied to Barkhausen Noise

A. H. Wooters; Amit P. Mehta; Andrea C. Mills; B. Alessandro; B. Gutenberg; D. S. Fisher; Djordje Spasojević; G. Durin; G. Durin; G. Grinstein; H. Ji; J. Ortín; J. P. Sethna; J. P. Sethna; J. P. Sethna; J. S. Urbach; J. Villain; James P. Sethna; Karin A. Dahmen; M. P. Lilly; Matthew C. Kuntz; Matthew C. Kuntz; O. Narayan; Olga Perković; Olga Perković; S. Field; S. Zapperi; W. Wu

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Universal Pulse Shape Scaling Function and Exponents: A Critical Test for Avalanche Models applied to Barkhausen Noise

Authors: A. H. Wooters
Amit P. Mehta
Andrea C. Mills
B. Alessandro
B. Gutenberg
D. S. Fisher
Djordje Spasojević
G. Durin
G. Durin
G. Grinstein
H. Ji
J. Ortín
J. P. Sethna
J. P. Sethna
J. P. Sethna
J. S. Urbach
J. Villain
James P. Sethna
Karin A. Dahmen
M. P. Lilly
Matthew C. Kuntz
Matthew C. Kuntz
O. Narayan
Olga Perković
Olga Perković
S. Field
S. Zapperi
W. Wu
Publication date: 7 December 2001
Publisher: 'American Physical Society (APS)'
Doi

Abstract

In order to test if the universal aspects of Barkhausen noise in magnetic materials can be predicted from recent variants of the non-equilibrium zero temperature Random Field Ising Model (RFIM), we perform a quantitative study of the universal scaling function derived from the Barkhausen pulse shape in simulations and experiment. Through data collapses and scaling relations we determine the critical exponents

\tau

and

1/\sigma\nu z

in both simulation and experiment. Although we find agreement in the critical exponents, we find differences between theoretical and experimental pulse shape scaling functions as well as between different experiments.Comment: 19 pages (in preprint format), 5 figures, 1 tabl

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