Condensed Matter Physics 238B

Winter 2007

Tuesday & Thursday, 12:30-1:50pm
FRH 2111

Instructor: Dr. Sasha Chernyshev, Associate Professor
Office: FRH 2158
Phone: (949)-824-6440
E-mail: sasha@uci.edu
Web page: http://www.physics.uci.edu/faculty/chernyshev.html
Office hours: open office policy

Introduction

This course is the second in a sequence of three Condensed Matter Physics courses.
It covers several broadly related topics. In all of them we use the quantum mechanics
and statistical physics to understand the processes in solids (condensed matter).

Topics to be covered

Phonons
- Lattice sums
- Normal modes, second quantization
- Specific heat
- Crystalline order in one- and two-dimensions
- Debye-Waller factor, Moessbauer effect
Interacting electrons
- non-interacting Fermi-gas
- Excitations: electrons, holes, e-h continuum
- Plasmon
- Lindhard dielectric function derivation
- plasmon with dispersion
- Landau damping
- Screening, singularity in it
- Friedel oscillations
Electron-phonon interaction
- Sound velocity in metals
- Sound attenuation
- Kohn effect
- Electron-phonon interaction Hamiltonian
- Acoustic case
- Coupling to optical phonons in polar crystalls
- Polaron, weak coupling
- Polaronic shift, mass renormalization
- 1D electron gas, Pierels instability
Transport phenomena
- Boltzmann equation
- Relaxation time approximation
- Electrical conductivity
- impurity scattering, e-e scattering, e-ph scattering
- Transport coefficients
- Thermo-electric effects, thermal conductivity
- Wiedemann-Franz law
- Hall effect
- Lattice thermal conductivity

Recommended Books

M. P. Marder, Condensed matter physics, published by John Wiley and Sons, Inc., 2000.

Principles of the Theory of Solids, by J. M. Ziman, Cambridge University Press; 2 edition (1979).

Solid State Physics, by N. W. Ashcroft and N. D. Mermin, Saunders College Publishing (1976).

Quantum theory of solids, by C. Kittel, published by John Wiley and Sons (1963).

Extra material

a few pages on interacting electrons from Ziman (reasonably close to the lectures), here.

some more pages (Ch. 5 and 6) from Kittel, here.

sound attenuation and electron-phonon interaction from Ziman, here.

e-ph + polaron (Ch. 7) from Kittel, here.

transport (Ch. 7) from Ziman, here.

Hall Effect (classical), problem 17.9, Marder, here.

Homeworks

Homeworks will be assigned weekly. They will be collected three-four times during the course on the "target" dates (approximately once every two-three weeks) and graded.
The target dates will be announced separately. The homework assignments will be due at the beginning of class. Late homework that is turned in within 24 hours of the deadline will be given half credit. No homework will be accepted after that.
You will be required to give a short presentation on a Condensed Matter topic of your choice in the end of the quarter.
The grade is 90% homework, and 10% presentaton.

Homework, weeks #1 and #2: Problems 1, 4, and 5 from Ch. 13, Marder's book.
Problem #A1: The chain has basis of 3 atoms with different masses. Describe qualitatively the phonon spectra of such a chain. Provide a sketch. (no calculations needed).
Problem #A2: Within the Debye approximation, calculate the lattice specific heat in the low-T and high-T regimes in (a) 1D and (b) 2D cases.

solutions

Homework, weeks #3 and #4: Problems are here.
solutions
Homework, weeks #5 and #6: Problems are here.
solutions
Homework, weeks #7 and #8: Problems are here.
solutions

Homework, weeks #9 and #10: Problems are here.
solutions