Some problems on spatial patterns in nonequilibrium systems
Yeung, Chuck
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https://hdl.handle.net/2142/23930
Description
Title
Some problems on spatial patterns in nonequilibrium systems
Author(s)
Yeung, Chuck
Issue Date
1989
Doctoral Committee Chair(s)
Oono, Yoshitsugu
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
spatial patterns
nonequilibrium systems
1-d cellular automata (CA) model
chemical turbulence
dynamical scaling hypothesis
phase ordering dynamics
Language
en
Abstract
"In this thesis, we study the evolution of spatial patterns in two nonequilibrium
systems.
In Chapter 1, we study the steady state of a 1-d cellular automata (CA)
model of chemical turbulence. Empirically there are two interesting types
of space-time patterns (depending on model parameters): aS phase which
seems to contain solitons and aT phase which seems to be turbulent. We
show that the macroscopic phases can be predicted from the microscopic
dynamics. We define the thermodynamic limit of the steady state of CAs
and show that the steady state of the S phase is trivial and the T phase
exhibits a Gibbs state. We explicitly calculate the T phase steady state
and find an approximate form for the energy functional which generates the
Gibbs state. We show that there is no adequate characterization of turbulent
behavior in CAs and introduce a quantity the ""P-entropy"" which is positive
if the CA patterns are turbulent and zero otherwise. We show the P-entropy
for the T phase is positive.
In Chapter 2, we consider the consequences of the dynamical scaling
hypothesis in phase ordering dynamics. We assume that the dynamics are
governed by the Cahn-Hilliard-Cook (CHC) and time-dependent GinzburgLandau
equations and show that the scaling hypothesis restricts the asymptotic
growth rate of the length-scale of the patterns and the small wavevector
behavior ofthe form factor. Specifically, if the form factor Sk(t) grows as k8
for small 6, then 6 ~ 4 (for the CHC dynamics). We find that experimental
data indicates 6 = 4. We also show that the CHC equation is sometimes
inadequate for describing phase ordering dynamics. An alternative to the
CHC model by Oono, Kitahara and Jasnow is examined. We find that many
features of phase ordering dynamics are robust with respect to changing the
dynamics."
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