PHYS 497X – Special Studies:Research
Prerequisites/Corequisites: Credit Hours: Min: 3; Max: Description:
PHYS 416L – Nuclear Radiation Physics Lab
Prerequisites/Corequisites: Take PHYS-416. (Required, Concurrent). Credit Hours: Min: ; Max: Description:
PHYS 406B – Advanced Computational Phys
Prerequisites/Corequisites: Credit Hours: Min: 3; Max: Description:
PHYS 406L – Nuclear Physics Laboratory
Prerequisites/Corequisites: Credit Hours: Min: ; Max: Description:
PHYS 401L – Nuclear Physics Laboratory
Prerequisites/Corequisites: Credit Hours: Min: ; Max: Description:
PHYS 397G – Special Topics
Prerequisites/Corequisites: Credit Hours: Min: 1; Max: Description:
PHYS 397B – Special Studies:Research
Prerequisites/Corequisites: Credit Hours: Min: 2; Max: Description:
PHYS 320 – Computational Statis & Thermal Phys
Prerequisites/Corequisites: Take PHYS-220 PHYS-301 PHYS-314 MATH-203 CS-190 CS-226 or MATH-213. (Required, Previous). Credit Hours: Min: 3; Max: Description: Analysis of the properties of many-particle systems at finite temperature using both analytical and numerical methods. Topics include heat, work, temperature, pressure, entropy, the laws of thermodynamics, engines, refrigerators, phases of matter, and phase transitions. These macroscopic […]
PHYS 314L – Modern Physics Lab
Prerequisites/Corequisites: Take PHYS-314. (Required, Concurrent). Credit Hours: Min: ; Max: Description:
PHYS 312L – Lasers & Optics Lab
Prerequisites/Corequisites: Take PHYS-312. (Required, Concurrent). Credit Hours: Min: ; Max: Description:
PHYS 314 – Modern Physics
Prerequisites/Corequisites: Take PHYS-202 MATH-202. (Required, Previous). | Take PHYS-314L. (Required, Concurrent). Credit Hours: Min: 4; Max: Description: Introduction to relativity and the quantum theory including their historical background, the experimental basis of these theories, and applications to atomic and molecular structure.
PHYS 302 – Electricity & Magnetism
Prerequisites/Corequisites: Take PHYS-202 PHYS-220 MATH-202. (Required, Previous). Credit Hours: Min: 3; Max: Description: Introduction to classical electromagnetic theory. The differential form of Maxwell’s equations will be developed and applied to various problems in electrostatics, magnetostatics, electromagnetic fields, and waves. Particular emphasis will be placed on radiation fields with applications to optics. Electric and magnetic properties […]