Professors Bloom, Cheyne, McDermott; Associate Professors Keohane, Thurman; Visiting Associate Professor Holt.
Chair: Jonathan W. Keohane


ASTRONOMY

ASTRONOMY 115. (4) INTRODUCTION TO ASTRONOMY WITH LABORATORY. An examination of astronomy: its methods and history, and the origin and development of the solar system, the galaxy, and the universe. Goals for this class include the implementation of observational techniques, the development of data analysis skills using current standard spreadsheet software, the development of scientific writing skills, and learning to use an astronomical telescope. Prerequisite: none. Offered: each semester.

ASTRONOMY 125. (3) LIFE IN THE UNIVERSE. This course concentrates on the astronomical and biological conditions which have made possible the development of life on Earth. Our knowledge of the cosmos is critically examined to estimate the probabilities for life to arise elsewhere. Methods of searching for intelligent extraterrestrial life are reviewed. This is a one-semester course intended for the non-physicalscience major. Prerequisite: none.

ASTRONOMY 210. (3) OBSERVATIONAL ASTRONOMY. Optical and radio astronomy are introduced, with an emphasis on measurement techniques, instrumentation, and data analysis. Prerequisite: Astronomy 115.

ASTRONOMY 310. (3) ASTROPHYSICS. The study of the physics of astronomical processes in order to understand what can be learned  from the radiations observed from astronomical objects. Prerequisites: Physics 132 and Mathematics 141. Offered: spring semester of oddnumbered years. (Cross-listed as Physics 310.)

PHYSICS

PHYSICS 101. (3) INTRODUCTION TO ENGINEERING PHYSICS. Introduction to the professions of engineering and engineering physics with emphasis on developing fundamental basis of scientific exploration into engineering using physics, communication, teamwork, creativity, and analysis. Prerequisite: None. Not open to juniors or seniors without prior consent from the professor.

PHYSICS 105. (3) PHYSICS AND ASTRONOMY OF SCIENCE FICTION. An overview of the physics and astronomy content of popular television, film and literature, with a focus on analyzing common science fiction tropes such as: intelligent life in the universe, robots, space travel, and teleportation. Prerequisite: none.

PHYSICS 106. (3) ELECTRONICS I. AAn inquiry-based approach to the study of electronics including transistors, integrated circuits, and digital logic. Prerequisite: none. Not open to juniors or seniors without prior consent from the professor.

PHYSICS 107. (3) ENERGY AND THE ENVIRONMENT. An introductory course focusing on the basic physical principles behind production, consumption, conservation and pollution due to the use of energy. Topics include fossil fuels, renewable energy sources, conservation techniques, transportation, and climate change. Prerequisite: none. Offered: every other fall semester of odd-numbered years.

PHYSICS 108. (3) METEOROLOGY AND CLIMATOLOGY. An elementary introduction to meteorology and climatology including properties of the atmosphere and their effects on the weather, climate change and global warming. Prerequisite: none.

PHYSICS 131. (3) FUNDAMENTALS OF PHYSICS I. A calculusbased introduction to classical mechanics. Topics include linear kinematics and dynamics, work and energy, momentum, gravitation, rotational kinematics, oscillations, fluids, and mechanical and sound waves. Corequisite: Physics 151. Offered: fall semester.

PHYSICS 132. (3) FUNDAMENTALS OF PHYSICS II. A calculusbased introduction to electromagnetism and modern physics. Electrostatics, the electric field and potential, electric current and circuits, magnetostatics, induction, light and optics, the atomic nature of matter, the structure of the atom, and the nucleus are studied. Prerequisite: Physics 131. Corequisite: Physics 152. Offered: spring semester.

PHYSICS 135. (3) THE PHYSICS OF SOUND. The course begins with an introduction to the basic physics of sound. Additional topics include a study of musical instruments, high-fidelity audio systems, speaker design and placement, microphones, and room acoustics. Prerequisite: none.

PHYSICS 215. (3) STATICS. An application of free-body force diagrams using vector methods to analyze systems in internal and external equilibrium. Other topics will include rigid bodies, centers of gravity, centroids, moments of inertia and applications to structural analysis. Prerequisite: Physics 132. Prerequisite or corequisite: Mathematics 142.

PHYSICS 220. (3) COMPUTATIONAL METHODS IN PHYSICS. An introduction to the techniques of using computers to solve problems in physics. These include numerical differentiation and integration, numerical modeling, and graphical presentation of data. The techniques learned are applied to solve interesting problems in physics. Previous programming experience and computer literacy are helpful but not expected. Prerequisite: Physics 131. Prerequisite or corequisite: Mathematics 141. Offered: fall semester.

PHYSICS 233. (3) MODERN PHYSICS. An introduction to modern physics, which includes a study of relativity, atoms, molecules, nuclei, waves, and spectra. Prerequisites: Physics 132 and Mathematics 142. Offered: fall semester.

PHYSICS 243. (3) ELECTRONICS II. An inquiry-based approach to the concepts and principles behind interfacing with specific application to experimental control and data collection through the use of microprocessors. Topics to be covered include analog to digital converters, digital to analog converters, and encoders. Prerequisite: Physics 106 or Physics 132.

PHYSICS 244. (3) EXPERIMENTAL PHYSICS. An instrumentation-based course that provides an introduction to modern measurement techniques, instrumentation, and data analysis. Topics include concepts of electronics, spectroscopy systems, and mechanical systems. Emphasis is placed on the principles of data collection and analysis. Prerequisite: Physics 132. Offered: spring semester.

PHYSICS 310. (3) ASTROPHYSICS. The study of the physics of astronomical processes in order to understand what can be learned from the radiation observed from astronomical objects. Prerequisites: Physics 131 and Mathematics 141. Offered: spring semester of oddnumbered years. (Cross-listed as Astronomy 310.)

PHYSICS 326. (3) MATHEMATICAL METHODS FOR PHYSICS AND ENGINEERING. Selected mathematical techniques most often used in physics are studied. Power Series, Fourier Series, linear transformations, ordinary and partial differential equations, Eigenvalues, Eigenvectors, complex variables, Legendre Polynomials, spherical harmonics, and Bessel Functions are among the topics considered. These techniques are applied to problems in electricity and magnetism, mechanics, acoustics, and quantum mechanics. Prerequisite: Physics 132. Prerequisite or corequisite: Mathematics 242. Offered: fall semester of odd- numbered years.

PHYSICS 331. (3) CLASSICAL MECHANICS. Particle dynamics is treated with special emphasis on harmonic motion, motion in a central force field, and the two-body problem. Prerequisite: Physics 131. Prerequisite or corequisite: Math 242. Offered: fall semester.

PHYSICS 332. (3) ELECTRICITY AND MAGNETISM. A study of electrostatics, dielectrics, and magnetostatics. Prerequisite: Physics 331. Offered: spring semester.

PHYSICS 333. (3) MODERN PHYSICS II. An extension of the material from Modern Physics I with topics to include atomic and molecular physics, multielectron atoms, semiconductor physics, nuclear and particle physics. Prerequisite: Physics 233. Prerequisite or corequisite: Mathematics 242. Offered: on sufficient demand.

PHYSICS 340. (3) ELECTROMAGNETIC WAVES AND OPTICS. Topics include transmission lines, electromagnetic waves, and light. In particular, refraction, polarization, diffraction, and emission mechanisms will be covered. Prerequisites: Physics 132. Prerequisite or corequisite: Mathematics 242. Offered: on sufficient demand.

PHYSICS 342. (3) THERMODYNAMICS AND STATISTICAL PHYSICS. An introduction to kinetic theory and thermodynamics, with a brief survey of statistical mechanics. Prerequisites: Physics 132 and Mathematics 142. Offered: spring semester.

PHYSICS 343. (3) FLUID MECHANICS. Topics include: properties of fluids, fluid statics, dimensional analysis, the Bernoulli equation, and the Navier-Stokes equations. These will include the conservation of mass, momentum, and energy in both integral and differential form. Prerequisites: Physics 132. Prerequisite or corequisite: Mathematics 242. Offered: on sufficient demand.

PHYSICS 441. (3) SOLID-STATE PHYSICS. An introductory course in solid-state physics and material science, with an emphasis on the applications of each topic to experimental and analytical techniques. Topics include crystallography, thermal and vibrational properties of crystals and semiconductors, metals and the band theory of solids, superconductivity, the magnetic properties of materials, and surface physics. Prerequisite: Physics 332. Offered: on sufficient demand.

PHYSICS 442. (3) QUANTUM MECHANICS.The physical foundations of the quantum theory are studied. Schroedinger’s Equation is introduced and used to analyze elementary aspects of the atom. Perturbation theory, the variational method, and other approximation methods are introduced. Prerequisite: Physics 233. Offered: on sufficient demand.


LABORATORIES

ASTRONOMY

ASTRONOMY 351-352. (2) ADVANCED LABORATORY. An independent research project will be conducted to answer a scientific question, to design an observational instrument, or to explore a pedagogical question, which will include data collection, analysis, interpretation, and hypothesis testing. Results will be presented through a written report and a presentation. Prerequisite: Astronomy 210 or consent of the instructor. Offered: 351 in the fall semester; 352 in the spring semester.

PHYSICS

PHYSICS 151. (1) GENERAL PHYSICS LABORATORY I. An experimental examination of a variety of physical phenomena, along with an introduction to laboratory techniques and procedure. Corequisite: Physics 131. Offered: fall semester.

PHYSICS 152. (1) GENERAL PHYSICS LABORATORY II. An experimental examination of a variety of physical phenomena, along with an introduction to laboratory techniques and procedure. Corequisite: Physics 132. Offered: spring semester.

PHYSICS 351-352. (2) ADVANCED LABORATORY. A laboratory course designed to acquaint the student with the instruments used in basic physical measurements and with the design of experiments. Prerequisite: consent of the instructor. Offered: 351 in the fall semester; 352 in the spring semester.

PHYSICS 451. (2) ADVANCED PROJECT I. A proposal for an independent project will be developed and preliminary investigation will be conducted. Prerequisite: Physics 244 and senior standing.

PHYSICS 452. (2) ADVANCED PROJECT II. An independent research project will be conducted to answer a scientific question, to design an experimental instrument, or to explore a pedagogical question which will include data collection, analysis, interpretation, and hypothesis testing. Results will be presented through a written report and a presentation that is consistent with professional standards. Prerequisite: Physics 451.

PHYSICS 461. (3) ADVANCED LABORATORY WITH DISTINCTION. An extended project conducted in collaboration with a faculty member, ordinarily resulting in publishable research. Prerequisite: consent of the instructor and a cumulative GPA of 3.2 or higher.

PHYSICS 462. (3) ADVANCED LABORATORY WITH DISTINCTION. A continuation of Physics 461 for projects found suitable. Prerequisite: consent of the instructor and a grade of B or higher in Physics 461.

updated 8/19/24