Carleton College

PHYS 123. What Physicists Do A program of five lectures by invited speakers that is intended to give students some perspective on the kinds of work done by people with a physics background. Visitors from industry, government, business, and research and educational institutions will discuss their work and work-related experiences. Prerequisite: Physics 131, 132, 141, 142, 151, 152, 153, or 165. 1 cr., S/CR/NC, NE, Spring—B. Titus

PHYS 131. Introduction to Physics: Newtonian Mechanics An introduction to classical mechanics using the Newtonian worldview. The kinematics and dynamics of some simple systems including objects in free fall, simple harmonic motion, planetary motion, and the motion of charged particles in electromagnetic fields are investigated using Newton's laws, vector analysis, and the conservation laws of linear momentum, angular momentum, and energy. Comfort with algebra and the integration and differentiation of elementary functions is assumed. Weekly laboratory work. Prerequisite: Mathematics 111, not open to students who have completed Physics 132, 141, or 142 at Carleton; Concurrent registration in Physics 131L. 3 cr., LS, QRE, Fall,Winter,Spring—E. Hazlett, A. Pattanayak

PHYS 132. Introduction to Physics: Gravity and the Earth An introduction to the basic principles of Newtonian mechanics and conservation laws using the earth and the gravitational force law as a conceptual framework. The many influences of gravity on the structure of the earth from its shape to the tides, and techniques for measuring gravity will be discussed. Comfort with algebra and the integration and differentiation of elementary functions is assumed. Weekly laboratory. Prerequisite: Mathematics 111, not open to students who have completed Physics 131, 132, 141, or 142 at Carleton; Concurrent registration in Physics 132L. 3 cr., LS, QRE, Not offered in 2015-2016.

PHYS 141. Introduction to Physics: Gravity and the Cosmos An introduction of basic principles of physics in the realm of planetary systems, black holes and dark matter in the universe. Gravity, conservation of energy and momentum will be used to explore large-scale phenomena in the cosmos. Comfort with algebra and the integration and differentiation of elementary functions is assumed. Weekly laboratory or observational work. Not open to students who have completed Physics 131, 132, or 142 at Carleton. Prerequisite: Mathematics 121 (completion or concurrent registration) and strong preparation in Physics 131.; Concurrent registration in Physics 141L. 3 cr., LS, QRE, Winter—C. Blaha

PHYS 142. Introductory Mechanics: Matter and Interactions An introduction to Newtonian mechanics using calculus. The kinematics and dynamics of objects in motion are investigated using Newton's laws and related conservation laws. Examples of systems studied include table-top objects, simple astronomical systems, or objects in harmonic motion. This section emphasizes a bottom-up atomic perspective and introduces a computational approach to allow the consideration of atoms and molecules inside solids as well. Weekly laboratory or computational work. Prerequisite: Mathematics 121 (completion or concurrent registration) and strong preparation in physics. Not open to students who have completed Physics 131, 132, or 141 at Carleton; Concurrent registration in Physics 142L. 3 cr., LS, QRE, Fall—A. Pattanayak

PHYS 151. Introduction to Physics: Relativity and Particles An introduction to principles of physics in the domain of the very small and very fast. Topics include the special theory of relativity, and selected applications to atomic, nuclear, and particle physics. Comfort with algebra and the integration and differentiation of elementary functions is assumed. Weekly laboratory work. Prerequisite: Mathematics 121 (completion or concurrent registration) and Physics 131 (completion or concurrent registration) or 132, 141 or 142; Concurrent registration in Physics 151L. 3 cr., LS, QRE, Fall,Winter,Spring—N. Christensen, E. Hazlett, W. Titus

PHYS 152. Introduction to Physics: Environmental Physics An introduction to principles of physics and their application to the environment. Topics include energy and its flows, engines, energy efficiency, energy usage and conservation in vehicles and buildings, the atmosphere, and climate change. Comfort with algebra and the integration and differentiation of elementary functions is assumed. Weekly laboratory work or field trips. Prerequisite: Physics 131 (completion or concurrent registration), 132, 141 or 142 and Mathematics 121 (completion or concurrent registration); PHYS 152L. 3 cr., LS, QRE, Spring—A. Pattanayak

PHYS 153. Fluid and Waves A study of the properties of fluids (both static and dynamic) and the principles of waves and wave motion (including both sound and light). Topics include simple harmonic motion, buoyancy and Archimedes' principle, Bernoulli's equation, viscosity, Poiseuille's equation, standing waves, musical instruments, and the Doppler effect. One laboratory per week. Prerequisite: Physics 131, 132, 141 or 142 and Mathematics 111; Concurrent registration in Physics 153L. 3 cr., LS, QRE, Fall—F. McNally

PHYS 165. Introduction to Electricity, Magnetism, and Optics A study of the principles of electricity, magnetism, and optics with an emphasis on real-world applications including electronics, laser physics, astronomy, and medicine. Topics include electric and magnetic fields, electric potentials, DC and AC circuits, geometric and wave optics, and relevant properties of matter. Designed for science majors who want additional background in physics. Comfort with algebra and the integration and differentiation of elementary functions is assumed. One laboratory per week. Prerequisite: Physics 131, 132, 141 or 142, and Mathematics 121 ; Concurrent registration in Physics 165L. 6 cr., LS, QRE, Winter—M. Baylor

PHYS 228. Atomic and Nuclear Physics An elementary but analytical introduction to the physics of atoms and nuclei. Topics include the particle aspects of electromagnetic radiation, an introduction to quantum mechanics, the wave aspects of material particles, the structure of atoms, X-ray and optical spectra, instruments of nuclear and particle physics, nuclear structure and elementary particles. One laboratory per week. Prerequisite: Physics 151; Concurrent registration in Physics 228L. 6 cr., LS, QRE, Fall—E. Hazlett

PHYS 229. Analytical Mechanics An analytical treatment of classical mechanics from a Lagrangian and Hamiltonian standpoint. Equations of motion and their solutions are studied with special emphasis on the harmonic oscillator and central-force problems. Prerequisite: Physics 131, 132, 141, or 142 and Mathematics 211; or permission of the instructor. 3 cr., NE, Winter—W. Titus

PHYS 230. Computational Mechanics A numerical treatment of classical mechanics concentrating on examples which are difficult, if not impossible, to solve analytically. Topics may include examples from astrophysics and chaotic dynamics. Prerequisite: Physics 229. 3 cr., NE, Winter—W. Titus

PHYS 234. Computer Simulations in Complex Physical Systems The development of techniques to study complex physical systems from a probabilistic and numerical standpoint using Mathematica. Subject material is applicable to all the sciences and mathematics. Some topics considered are random walks, percolation clusters, avalanches, traffic flow, the spread of forest fires and diseases, and a brief introduction to Bayesian statistics. No Mathematica skills are assumed. Prerequisite: Physics 131, 132, 141, or 142, or instructor permission. 6 cr., LS, QRE, Offered in alternate years. Spring—W. Titus

PHYS 235. Electricity and Magnetism Electric and magnetic fields in free space, and their interactions with charges and currents. Topics include DC and AC circuits, Maxwells's equations, and electromagnetic waves. Weekly laboratory work. Prerequisite: Physics 151, 161, or 165, and Mathematics 211 or instructor permission; Concurrent registration in Physics 235L. 6 cr., LS, QRE, Spring—M. Baylor

PHYS 261. Medical Physics The course covers the basic concepts of medical physics. Particular attention is paid to electromagnetism, mechanics and nuclear physics when applied to medical and biological phenomena. Topics include medical imaging techniques, nuclear medicine radiation protection, dosimetry, and physics in biology. Students will visit medical imaging facilities. Note that this course is not appropriate for pre-medical, pre-dental or pre-veterinary requirements. Prerequisite: Physics 151, 152, 153, or 165. 6 cr., NE, Not offered in 2015-2016.

PHYS 335. Quantum Mechanics An examination of the structure of non-relativistic quantum mechanics and how this theory differs from those of classical physics. Topics include the mathematics of Hilbert space, the postulates of quantum mechanics, the motion of a particle in one dimension (including the free particle and the simple harmonic oscillator), the Heisenberg uncertainty principle, and spin. Multidimensional applications will include the harmonic oscillator, the hydrogen atom. Approximation techniques and applications will be presented. Prerequisite: Physics 228, 229/230 and Mathematics 232. Familiarity with matrix algebra is assumed. 6 cr., NE, Winter—A. Pattanayak

PHYS 341. Waves The analysis of wave phenomena, including normal mode expansions, the wave equation and boundary value problems, and interference, diffraction, and polarization. Applications are made to mechanical, sound, water and electromagnetic waves with particular emphasis on electromagnetism and optics. Prerequisite: Physics 229 and 235, and Mathematics 232. 6 cr., NE, Offered in alternate years. Winter—C. Blaha

PHYS 342. Contemporary Experimental Physics A study of experimental techniques and apparatus basic to the measurements which underlie and validate contemporary theories in physics. Topics include electrical measurements, data analysis and statistics, optical and laser techniques, particle detectors, and time coincidence techniques. Applications are made to experiments such as magnetic resonance, Mossbauer and nuclear spectroscopy and laser optics. Class time is devoted to studying the measurement techniques and considering phenomenological models of the effects observed in the laboratory. One laboratory per week. Prerequisite: Physics 228 and 235 and 1-300 level Physics course; Concurrent registration in Physics 342L. 6 cr., LS, QRE, Spring—M. Eblen-Zayas

PHYS 343. Electronics A study of the electrical circuits and electronics underlying modern physics instrumentation. Includes an introduction to microprocessor and microcomputer design. Approximately equal emphasis on analog and digital electronics. One laboratory per week. Prerequisite: Physics 235; Concurrent registration in Physics 343L. 6 cr., LS, QRE, Fall—N. Christensen

PHYS 344. Classical and Quantum Optics A junior/senior level course in classical and quantum optics. Includes the phenomena of interference, diffraction and coherence and quantum optical applications, such as unique statistical states of light or the operation of a laser. Modern applications of these areas are studied through such topics as fiber optics telecommunication, optical data storage, or manipulation of atoms by light. Prerequisite: Physics 235 and Mathematics 232. 6 cr., NE, Offered in alternate years. Not offered in 2015-2016.

PHYS 345. Advanced Optics This is a laboratory course that will serve as a follow-up to Physics 344, Classical and Quantum Optics. Students will conduct a number of experiments pertaining to optical phenomena. The experiments will display effects pertaining to classical, quantum, and non-linear optics. The lab will take place once a week for four hours each session. Prerequisite: Physics 344 or permission of the instructor. 2 cr., LS, QRE, Offered in alternate years. Not offered in 2015-2016.

PHYS 346. Thermodynamics and Statistical Mechanics The fundamentals of classical thermodynamics and statistical mechanics. Topics include the laws of thermodynamics; heat engines and refrigerators; the Maxwell-Boltzmann distribution; the various canonical distributions; the statistical concepts of temperature and entropy; Fermi-Dirac, and Bose-Einstein distributions with applications to black-body radiation, phonons, and electrons in solids; the Ising model; and an introduction to critical phenomena. Prerequisite: Physics 228. 6 cr., NE, Fall—A. Pattanayak

PHYS 347. General Relativity Einstein's theory of general relativity is developed from basic physical principles. Also presented is the mathematics of curved space time. Astrophysical applications of general relativity, including spherically symmetric objects, black holes, cosmology and the creation and detection of gravitational waves are given. Prerequisite: Physics 230 and 235. 6 cr., NE, Not offered in 2015-2016.

PHYS 352. Advanced Electricity and Magnetism The classical theory of fields and waves. Electromagnetic theory including Maxwell's equations, radiation and relativity. Prerequisite: Physics 235, Mathematics 341 strongly recommended. 6 cr., NE, Spring—N. Christensen

PHYS 354. Solid State Physics An introduction to the physics of solids. Particular attention is paid to the properties exhibited by atoms and molecules because of their association and regular periodic arrangement in crystals. Topics include crystal structure and diffraction, the reciprocal lattice, phonons and lattice vibrations, thermal properties, free-electron theory and band structure. Prerequisite: Physics 335 or 346. 6 cr., NE, Offered in alternate years. Spring—E. Hazlett

PHYS 355. Topics in Advanced Classical Mechanics Lagrangian and Hamiltonian methods including central force motion, coupled harmonic oscillators, and the study of continuous systems. Additional subjects may include fluid dynamics, classical field theory or other specialized topics. Prerequisite: Physics 229 and 230. 6 cr., NE, QRE, Fall—W. Titus

PHYS 356. Special Project Individual projects in experimental, theoretical, or computational physics. Available projects are often related to faculty research interests or to the development of course-support materials, such as new laboratory exercises. Prerequisite: Permission of the instructor. 2 or 3 cr., S/CR/NC, NE, Fall,Winter,Spring—Staff

PHYS 400. Integrative Exercise An extensive study of a specific topic in physics, culminating in a 60-minute presentation during winter or spring term and a 7500 word paper. Students may arrange to complete the bulk of their work during winter or spring term (Physics 400, 6 credits), or divide their effort between terms (Physics 400, winter, 3 credits; Physics 400, spring, 3 credits). 6 cr., S/CR/NC, NE, Winter,Spring—Staff

ASTR 100. Cosmology: A Beginner's Guide to the Universe A discussion of the changing view of our place in space, from the cosmologies of ancient civilizations to the twenty-first century picture of an accelerating universe. Topics will include basic principles of General Relativity, black holes and the curvature of space, and speculations about the ultimate fate of the universe. Designed to appeal to a wide audience of "cosmic thinkers," including both science and non-science majors. Some evening observing sessions will provide opportunity for viewing with the telescopes. Prerequisite: High school algebra and trigonometry.  6 cr., AI, WR1, Fall—C. Blaha

ASTR 110. Introduction to Astronomy An introduction to current astronomy with an emphasis on how we know what we know. Topics include the solar system; the life cycles of stars; pulsars, quasars, and black holes; and the history and future fate of the universe. No mathematics background beyond high school algebra and trigonometry is assumed. 6 cr., LS, QRE, Fall,Winter—F. McNally

ASTR 113. Observational and Laboratory Astronomy Theory and practice of basic techniques in observational and laboratory astronomy. Certain problems involve the use of the 16-inch and 8-inch telescopes. Prerequisite: Astronomy 100, 110, 127, 232, 233, Physics 228, 232, 233 or instructor permission. 3 cr., S/CR/NC, LS, QRE, Fall,Spring—J. Weisberg, C. Blaha

ASTR 127. Topics in Modern Astrophysics Special topics in modern astrophysics will be explored in order to understand the physical processes at work in a variety of cosmic settings. Possible topics include the solar weather and its impact on Earth, extra-solar planets, black holes, dark matter, gravitational lensing, large-scale structures and dark energy in an accelerating universe. Prerequisite: Astronomy 100, or 110, or Physics 131, 132, 141 or 142. 6 cr., NE, WR2, QRE, Spring—C. Blaha

ASTR 232. Astrophysics I Cross-listed with PHYS 232. A study of stellar structure and evolution with an emphasis on the physical principles underlying the observed phenomena. Topics include the birth, evolution, and death of stars, pulsars, black holes, and white dwarfs. Prerequisite: Physics 228, 229 & 230 or instructor permission. 6 cr., NE, QRE, Offered in alternate years. Fall—J. Weisberg

ASTR 233. Astrophysics II Cross-listed with PHYS 233. A study of galactic and extragalactic astronomy with an emphasis on the physical principles underlying the observed phenomena. Topics include the structure and dynamics of the Milky Way Galaxy and other galaxies, the interstellar medium, quasars and active galaxies, clusters and superclusters, and cosmology. Prerequisite: Physics 228, 229 & 230 or instructor permission. 6 cr., NE, QRE, Offered in alternate years. Not offered in 2015-2016.

ASTR 356. Special Project Individual projects in observational, theoretical, or computational astronomy. Available projects are often related to faculty research interests or to the development of course-support materials, such as new laboratory exercises. Prerequisite: Instructor Permission. 2 or 3 cr., S/CR/NC, NE, Fall,Winter,Spring—Staff