Overview of current areas of research in the broad discipline of physics, including the historical context of their development. Describes various career options in physics, including academia, government, and industry. Outlines the college physics curriculum and describes opportunities to participate in research at the university.

This course teaches how to use the computer to solve quantitative problems. This involves learning the skills to write computer programs dedicated to certain tasks, to visualize data graphically, to use scientific software, and to learn other practical skills that are important for a future career in the sciences.

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

Applications of nuclear physics and nuclear energy: Introduction to nuclear physics, radioactivity, radiation standards and units, interaction of radiation with matter, accelerators, x-ray generators, detectors, biological effects, nuclear medicine, nuclear fission and reactors, nuclear fusion. Three lecture hours. (Y) Prerequisite: PHYS 2620 or instructor permission.

Practical electronics for scientists, from resistors to microprocessors. Prerequisite: Instructor permission.

Energy has always been essential to civilization, and never more than in the modern world. But what is energy? Will affordable sources of energy disappear in our lifetimes? Will our thirst for energy inevitably lead to climate change? Physics 1110 helps answer these questions, explaining the physical nature of energy, the ways we produce and consume it, and how changes in energy technology will shape our future. Requires high-school algebra.

In this class you will get a chance to explore the scientific wonders of the universe. Topics vary each semester but generally include: motion, energy, waves, electricity, magnetism, sound, light, relativity, atomic structure, molecules, quantum physics, the nucleus, chemistry, meteorology, geophysics, the solar system, stars, and cosmology. PHYS 1010 requires limited math, but has wide applications like electronics, wifi, rockets, satellites, nuclear reactors, lasers, climate change, earthquakes, the tides, eclipses, plate tectonics, fossil fuels, telescopes, solar energy, and the origin of universe. PHYS 1010 is for non-science majors. Premedical and pre-dental students should take PHYS 2010, 2020.

Includes Maxwell's equations; electromagnetic waves and their interaction with matter; interference, diffraction, polarization; waveguides; and antennas. Prerequisite: PHYS 3420.

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.

Second semester of the introductory physics sequence recommended for prospective physics majors. Topics include electricity, magnetism, circuits and optics. Emphasis is on building foundations for future studies in physics. Three lecture hours. PHYS 1420 or PHYS 1425; co-requisite MATH 2310; or instructor permission