Introduces the physical basis of quantum mechanics, the Schroedinger equation and the quantum mechanics of one-particle systems, and stationary state problem. Prerequisite: Twelve credits of 3000-level physics courses and MATH …
Includes angular momentum theory, techniques of time-dependent perturbation theory, emission and absorption of radiation, systems of identical particles, second quantization, and Hartree-Fock equations. Prerequisite: PHYS 7610 or instructor permission.
Independent research or practical training supervised by a faculty member. May be repeated for credit.
Studies nonlinear optical phenomena; the laser, sum, and difference frequency generation, optical parametric oscillation, and modulation techniques. Prerequisite: PHYS 5310 and exposure to quantum mechanics.
Studies the principles and techniques of atomic physics with application to selected topics, including laser and microwave spectroscopy, photoionization, autoionization, effects of external fields, and laser cooling. Prerequisite: PHYS 7620 …
The description and basic theory of the electronic properties of solids including band structure, electrical conduction, optical properties, magnetism and super-conductivity. Prerequisite: PHYS 7620 or instructor permission.
Introduces the quantization of field theories, including those based on the Dirac and Klein-Gordon equations. Derives perturbation theory in terms of Feynman diagrams, and applies it to simple field theories …
Applies field theory techniques to quantum electrodynamics and to the renormalization-group description of phase transitions. Introduces the path integral description of field theory. Prerequisite: PHYS 8630.
Discusses nuclear theory and experiment from the modern perspectives of the fundamental theory of the strong interaction: Quantum Chromodynamics (QCD).
Introduction to the Standard Model of Electroweak and Strong Interactions, to be followed by physics beyond the Standard Model, including aspects of Grand Unification, Supersymmetry, and neutrino masses.