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https://hdl.handle.net/2142/25248
Description
Title
Studies in random Ising spin systems
Author(s)
Cheung, Ho Fai
Issue Date
1986
Doctoral Committee Chair(s)
Wortis, M.
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
Ising spin systems
random bonds
random fields
phenomenological renormalization
transfer matrix
Language
en
Abstract
We give a brief survey of Ising spin systems in the presence of
random bonds or random fields. Specific calculations are done on the twodimensional
short-ranged random-bond model and the three-dimensional
random-field model.
The phenomenological renormalization group and the transfer-matrix
method are generalized to random systems and applied to the random-bond
Ising model, also called the Edwards-Anderson spin-glass model. Results
show that the two-dimensional Edwards-Anderson model has a spin-glass
transition at zero temperature, in agreement with other calculations. We
obtain an accurate estimate of the correlation-length exponent. We also
find unexpectedly different critical behavior for different bond
distributions.
A simple renormalization-group calculation is applied to the twodimensional
random-bond Ising model with non-zero-mean bond strength.
Our result fails to confirm McMillan's result that there are two different
critical behaviors along the ferromagnetic phase boundary.
McMillan's domain-wall renormalization group is applied to the three
-dimensional random-field Ising model. Numerical results show that the
critical behavior of this model is controlled by a fixed point at zero
temperature. The exponents are estimated. We find that, whenever there
is a relevant zero-temperature fixed point, the singular part of the free
energy is not of the usual form: The leading exponent that describes the
renormalization-group flow towards zero temperature is relevant to the
critical behavior. One of the consequences is that the hyperscaling law is
modified. This new picture explains many experimental results for dilute
antiferromagnets, ·which are experimental realizations of the random-field
Ising model. We also discuss the possibility of a first-order transition
for this model.
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