105. Physics for Life

An inquiry-based introduction to the concepts of physics and physical science. Through in-depth study of simple physical systems, students gain direct experience with the process of science. The content of the course varies and will concentrate on one or two of the following topics: properties of matter, heat and temperature, light and color, magnets, electric circuits, and the physics of motion. No mathematical prerequisites beyond those of secondary school algebra and geometry.

Meets general academic requirement S.

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111. Introduction to Astronomy

A study of the structure, motions, and evolution of the bodies of the physical universe. Emphasis is given to understanding physical principles and the techniques used by astronomers to study the universe. Topics of special interest include the structure of the solar system, the properties of stars, stellar evolution and collapse, the structure of galaxies, and cosmology.

Meets general academic requirement S.

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113. Cosmology: The Scientific Exploration of the Universe

We are continually seeking the answers to the age-old questions about the origin, age, composition, structure, and the ultimate fate of the universe. Just as the cosmos is changing, our views of the cosmos are changing as new observations and interpretations emerge. This course will examine the generally accepted cosmological models, and the personalities responsible for these models, from the time of the ancient Greeks up to the present. Each of these models will be examined in light of the observational data available at the time. Primary emphasis will be given to understanding the most current observations about the universe and the prevailing inflationary Big Bang model of the universe. Offered as a course designed for Muhlenberg Scholars.

Meets general academic requirement S.

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121. General Physics I

An introductory, calculus-based physics course. This activity-based course meets for two two-hour sessions in the laboratory, where concepts are introduced through experimentation and other hands-on activities. Follow-up discussions, demonstrations, and problem solving are emphasized during lecture periods. Topics covered include one- and two-dimensional kinematics and dynamics, momentum, energy, rotational kinematics and dynamics.

Prerequisite: MTH 121 Calculus I should be previously completed or enrolled concurrently.

Meets general academic requirement S.

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122. General Physics II

Extends the energy ideas introduced in PHY 211 General Physics I into the ideas of thermodynamics. It also introduces electrostatics, dc circuits, magnetism and electromagnetic induction, and some topics from modern physics. This course follows the same weekly format as General Physics I.

Prerequisite: PHY 121 General Physics I

Meets general academic requirement S.

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213. Modern Physics

An introduction to twentieth-century developments in physics, with an emphasis on the special theory of relativity; Rutherford scattering; introduction to quantum theory; atomic structure; nuclear and particle physics.

Prerequisite: PHY 122 General Physics II

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216. Analog & Digital Circuits

Through a mix of classroom work, computer simulations and laboratory work, students will build and analyze analog and digital circuits found in many scientific and computer applications. Specific topics include passive and active filters, electronic feedback, operational amplifiers, oscillators, A/D and D/A conversion, digital waveshaping and instrumentation. This course meets in the laboratory for two hours, twice a week, and will be offered in alternate years.

Prerequisite: PHY 122 General Physics II

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226. Optics: From Lenses to Lasers

Through laboratories and simulations, the student will explore the field of optics, starting with the fundamentals of waves and electromagnetic theory, through geometrical and physical optics, and culminating in the study of selected topics from modern optics. The modern topics may include lasers, optical data processing, holography or nonlinear optics. This course meets for two hours, twice a week, and will be taught in a laboratory/discussion format. The course will be offered in alternate years.

Prerequisite: PHY 122 General Physics II

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241. Thermal & Statistical Physics

The laws of thermodynamics, their consequences and applications. Kinetic theory of an ideal gas and an introduction to statistical mechanics.

Prerequisite: PHY 122 General Physics II

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250. Simulating Science

Computer simulations are an integral part of contemporary basic and applied science and computation is becoming as important as theory and experiment. The ability “to compute” is now part of the essential repertoire of research scientists. This course will introduce students to methods of computer simulation with applications to biology, chemistry, physics and environmental science. Possible topics include: how populations change with time (biology), the kinetic theory of gases (chemistry), the effect of air resistance on falling objects (physics), and the change over time of pollution levels in lakes (environmental science). No programming experience is required; elements of structured programming and C++ will be presented as needed.

Prerequisite: PHY 121 General Physics I

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313. Nuclear & Particle Physics

Properties of nuclei; theories and models of nuclear structure; natural radioactivity; nuclear forces and reactions; elementary particles.

Prerequisite: PHY 213 Modern Physics

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319. Analytical Mechanics

A detailed study of the kinematics and dynamics of particles, systems of particles, and rigid bodies. Topics considered include projectile motion; the gravitational force and its influence on earthbound and heavenly bodies; rotating coordinate systems; and scattering theory.

Prerequisite: PHY 122 General Physics II and MTH 122 Calculus II

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321. Advanced Mechanics

A course designed to broaden and deepen the understanding of classical physics. Topics to be studied include Lagrangian and Hamiltonian mechanics; the mechanics of continuous media; the theory of small vibrations; perturbation theory; and relativistic dynamics.

Prerequisite: PHY 319 Analytical Mechanics

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329. Electromagnetism

A study of electrostatics, magnetostatics, electrical currents and their effects. Maxwell’s equations are derived. Vector methods are stressed and field notation is used.

Prerequisite: PHY 319 Analytical Mechanics

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331. Advanced Electromagnetic Theory

Deviation of the wave equations from Maxwell’s equations. Wave theory is explored in detail, including derivation of the fundamental principles of wave optics.

Prerequisite: PHY 329 Electromagnetism

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341. Introduction to Quantum Mechanics

Origin of quantum concepts; the wave function and its interpretation; the Schrodinger equation; treatment of the free particle; potential barriers and wells; the linear harmonic oscillator and the hydrogen atom. Representation of dynamical variables as operators and matrices; introduction to perturbation theory.

Prerequisites: PHY 213 Modern Physics and PHY 319 Analytical Mechanics

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351. Solid State Physics

Study of the properties of crystalline solids. Starting with a study of crystal structure, reciprocal lattice structure, energy bands, and the free electron gas, physical models will be developed to explain the electrical, magnetic, thermal and optical properties of solids.

Prerequisite: instructor permission

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