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.

Discusses thermodynamics and kinetic theory, and the development of the microcanonical, canonical, and grand canonical ensembles. Includes Bose-Einstein and Fermi-Dirac distributions, techniques for handling interacting many-particle systems, and extensive applications to physical problems.

Approximately five experiments drawn from the major fields of physics. Introduces precision apparatus, experimental techniques, and methods of evaluating experimental results. Outside report preparation is required. Six laboratory hours. Prerequisite: PHYS 2640 or PHYS 3140

Group problem solving, data acquisition and analysis, and application of physics to real life scenarios in the framework of classical mechanics and thermodynamics. The course is geared towards STEM majors and required for engineering and physics majors. Co-requisites: PHYS 1425 or 1420.

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 5210, 5220, or instructor permission.

Applications of physical principles to a diverse set of phenomena: order of magnitude estimates, dimensional analysis, material science and engineering, astrophysics, aeronautics and space flight, communications technology, meteorology, sound & acoustics and fluid dynamics. Not all topics will be covered in every course. Three lecture hours. (Y) Prerequisite: PHYS 2620 or instructor permission.

Studies subatomic structure; basic constituents and their mutual interactions.

Development of the theory of special relativity, relativistic electrodynamics, radiation from moving charges, classical electron theory, and Lagrangian and Hamiltonian formulations of electrodynamics. Prerequisite: PHYS 7420 or instructor permission.

Surveys computational methods for problem solving in the physical sciences. Topics include numerical precision and efficiency, solutions of differential equations, optimization problems, Monte Carlo simulation, statistical methods, and data analytics. Tools for data visualization and use of libraries in both C/C++ and Python will be explored. Prerequisites: PHYS 2410 or PHYS 2415, PHYS 2620, and programming experience in Python and/or C.

Selected experiments in mechanics, thermodynamics, electricity and magnetism, optics, and modern physics. One lecture hour and four laboratory hours per week. Prerequisites: PHYS 1429, PHYS 2419; co-requisite: PHYS 2620.