Basic physics principles of energy sources and energy production, conversion, distribution, and storage. This course will focus on the basic physics principles and applications of engines, nuclear energy, solar power and photovoltaic, geothermal, wind and hydropower, fuel cells, batteries, bioenergy and fossil energy, as well as energy harvesting in the internet age. We will also learn a closely related topic of physics of climate and "drawdown". The course will conclude with the outlook of renewable energies. Three lecture hours. Prerequisite: PHYS 2620 or instructor permission.

For non-science majors. Examines how new understandings of the natural world develop, starting with the ancient world and emphasizing two famous scientists as case studies. Galileo was the first to make subtle use of experiment, while Einstein was the first to realize time is not absolute and that mass can be converted to energy.

Includes temperature and the laws of thermodynamics; introductory treatments of kinetic theory and statistical mechanics; and applications of Boltzmann, Bose-Einstein, and Fermi-Dirac distributions. Recommended Prerequisites: MATH 3250, PHYS 2620, and PHYS 2720.

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.

Group problem solving, data acquisition and analysis, and application of physics to real life scenarios in the framework of electricity and magnetism. The course satisfies the requirements for pre-health students. Co-requisites: PHYS 2020. Prerequisite: PHYS 2030

Group problem solving, data acquisition and analysis, and application of physics to real life scenarios in the framework of electricity and magnetism. The course is geared towards STEM majors and required for engineering and physics majors. Co-requisites: PHYS 2415 or 2410. Prerequisite: PHYS 1429

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 satisfies the requirements for pre-health students. Co-requisites: PHYS 2010

First semester of introductory physics sequence recommended for engineers. Topics include particle kinematics and dynamics, energy and momentum conservation, rotational motion, fluids, oscillatory motion, waves, sound, and thermodynamics. Emphasis is on development of skills for practical applications. Three lecture hours. Co-requisite: MATH 1320 or equivalent.

Second semester of introductory physics sequence recommended for engineers and other scientists. Topics include electricity, magnetism, circuits and optics. Emphasis is on development of skills for practical applications. Three lecture hours. Prerequisites: PHYS 1420 or PHYS 1425; co-requisite: MATH 2310; or instructor permission.

Discusses matrices, complex analysis, Fourier series and transforms, ordinary differential equations, special functions of mathematical physics, partial differential equations, general vector spaces, integral equations and operator techniques, Green's functions, group theory. Prerequisites: MATH 5210 and 5220 or instructor permission.