Physics 532 - Spring 2003 (Sec 85360, 3 hrs)

Order and Disorder of Condensed Matter

Please note that office hours on Monday Feb 17 are cancelled; instead I will have office hours Friday Feb 14, 1100-1200 in 2065 SEL.

Lectures: 136 SES   T 3:30-4:45, Th 3:30-4:45
Lecturer: John Marko, 6-6064, jmarko@uic.edu
Office Hours: M 2-4 PM, 2065 SEL or by appointment

Homework Grader: Yan Jie, 6-6105 ,yanj@callan.phy.uic.edu

Formally Required Prerequisite: Physics 531
Informally Required Prerequisites: Physics 461 or 561, Physics 511/512
Required Textbook: NONE

Problem Sets:
PS1: Problems 1 through 5 in notes, due Thursday January 30, solutions (PDF)
PS2: Problems 6 through 10 in notes, due Tuesday February 18, solutions (PDF)
PS3: Problems 11 through 15 in notes, due Tuesday March 11, solutions (PDF)
PS4: Problems 16 through 20 in notes, due Thursday March 27,solutions (PDF)
PS5: Problems 21 through 25 in notes, due Tuesday April 15, solutions (PDF)
PS6: Problems 26 through 28 in notes, due Thursday May 1, solutions (PDF)

Examinations: None

Grades: Assigned based on problem set grades

Suggested Reading:
H. E. Stanley, Introduction to Phase Transitions and Critical Phenomena (Oxford, 1971, 1987)
S.-K. Ma, Frontiers in Physics 46, Modern Theory of Critical Phenomena (Addison-Wesley 1976)
N. Goldenfeld, Frontiers in Physics 85, Lectures on Phase Transitions and the Renormalization Group (Addison-Wesley, 1992)
P. Chaiken and T. Lubensky, Principles of Condensed Matter Physics (Cambridge, 1995)

This course will present a basic description of phase transitions in a variety of condensed matter systems. The emphasis will NOT be mathematical (below that of Physics 501/502) although a background in basic methods of statistical mechanics (at the Physics 461 level) will be helpful. This course is NOT a substitute for Physics 561 !

Marks will be assigned on the basis of homework problems. Papers can be written on subjects related to the course if students like.

Lecture notes (html and pdf formats)

Curriculum

I   Basics
interactions, correlation functions, screening
phase transitions and order parameters
microscopic models vs hydrodynamic limit
mean-field theory of scalar order parameter
continuous symmetry (Mermin-Wagner theorem)
random fields and spin glasses

II   Kinetics and dynamics
Brownian dynamics
critical slowing down at second-order phase transitions
kinetics of first-order phase transitions (domain growth)
nonthermal fluctuations

III  Applications
superconductivity
crystallization
liquid crystals
interface fluctuations (roughening transition of a solid, lipid bilayers)
polymers (random walk, self-avoidance, polymer collapse)
biophysical applications of condensed matter theory

File translated from TEX by TTH, version 2.53.
On 7 Jan 2003, 13:03.