Course Outline

Version of November, 1996 --- may be modified as semester progresses

PART I: Introduction and Basic Methods

Computational Aspects.

Basic Numerical Methods.

PART II: Single-Particle and Many-Independent-Particle Problems

Solving the time-independent Schr. Eq. in 1 dimension (ordinary diff. eq.)

Radial equations for spherically symmetric problems

Hartree-Fock theory

Hartree-Fock solution for atoms

Project III of Koonin - working programs for atoms with Z<10
Examples of solutions for ground and excited states
Comparison of energies from Koopman's theorem and self-consistent solutions ("Delta H-F")

Density Functional Theory

Functionals in quantum mechanics
The Hohenberg-Kohn Theorem for many-body interacting systems
Kohn-Sham approach for solving for ground state of a many-body interacting particle system as a self-consistent problem of many-non-interacting particles
Methods for self-consistency
Application to the atomic problem
Modifying Hartree-Fock program for Hartree-density-functional calculations
- Matching logrithmic derivative x=d (log psi)/dr for wavefunction
- Theorem relating dx/dE to integrated charge
- Algorithm for solving radial Schr. Eq.

Scattering theory, phase shifts, and ab initio pseudopotentials

Solving Schroedinger Eq. in a basis: Matrix operations

Comparison of Finite difference discrete algorithms with matrix representations in a basis
Variational properties
Basis functions for atomic calculations. (Gaussian, Slater)
Calculations for molecules (and atoms) -- Beyond this course to construct general programs
Calculations with Gaussian program "Quantum Chemistry" package

Hartree-Fock calculations for problems in nuclei

Independent electrons in crystals

The reciprocal lattice and Brillouin Zone
The Bloch theorem for excitations in a periodic system
Solution for electrons in solids in a plane wave basis
Construction of a working program for crystals, using pseudopotentials and matrix diagonalization
Approximate solutions using the Harris functional
Discussion of full self-consistent solutions

Iterative methods

Thermal simulations of matter

Solving the single-particle time-dependent Schr. Eq. (partial diff. eq.)

PART III: Many-Interacting-Particle Problems

The problem: basis sizes which grow as N!

Prototype many-body problems

The Lanczos method (exact diagonalization) for the lowest states

Applications to finite temperature statistical quantum mechanics (may be omitted)

Monte Carlo methods

High dimensional integration by statistical sampling
Variational Monte Carlo with a trial correlated wavefunction
- Slater-Jastrow two-body correlations
- Gutzwiller wavefunctions for the Hubbard model
- Random walks, the Metropolis algorithm. Estimation of correlation and convergence
Diffusion Monte Carlo methods
- Project VIII of Koonin - exact solution of hydrogen molecule
- Comparison with Hartree-Fock, DFT (using Gaussian program)
- Discussion of the "sign problem" for Fermions

Perturbation Methods

The idea of quasiparticles and Fermi liquid theory
Calculation of quasiparticle energies using low-order perturbation expressions with approximate dynamically screened interactions
The GW method for quasiparticle energies
Simplifications in the limit of large degeneracy and large dimension

Other

Student project reports.

Special Topics which may be included at intervals during course

Perturbation theory: 2n+1 theorem
Optimization Techniques; Global minimization methods such as conjugate gradient and simulated annealing.
Variational Quantum Monte Carlo calculation on a lattice (e.g. Hubbard Model) or continuum problem (e.g. $ ^{4}He$)
Lattice Gauge Calculation and Theory
Relativistic models, Klein Gordon Equation for atoms
Berry's phases and polarization in extended systems
Charged particles in magnetic fields
Quantum Hall Effect
Particles in random potentials - disorder
Simple quantum system coupled to heat bath