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The Physics Major

Introduction
Requirements for the B.S. Degree in Physics
Suggested Programs of Study
Minor in Physics
Physics Department Courses
Physics Department Staff
Physics Major Checklist
Physics Minor Checklist

I. Introduction

Am I interested in discovering how things work?
Am I more interested in discovering how the same ideas can explain a variety of different devices or problems rather than a single one?
Am I more interested in finding exact, quantitative explanations rather than being satisfied with generalities?

Most physicists would answer "yes" to all three questions. What does a physicist do? Solid-state physicists investigate the properties of materials such as metals, alloys, semiconductors and insulators. The transistor, the best known result of their research, is so widely used that every home has scores of them in television sets, stereos, radios, pocket calculators, and electronic ignitions on cars. Optical physicist are interested in light--how to generate it, how to control it, how to describe it and how to use it. They study how the electrons in an atom or molecule interact with light, and thus learn how the electrons interact with each other. Not only is the laser a workhorse in the research laboratory, but you probably encounter a laser scanner every time you go through the grocery store checkout. Experimental physicists measure the response of the system to an applied force, or an electromagnetic field, or a sound wave, or some other probe. Theoretical physicists calculate the response of the system based on model. Comparison of the measured and calculated values allows us to refine our understanding of the basic law of nature.

The Colorado State University Physics major is designed to give each student a good basic background in physics, but still allow the flexibility to plan a career in any one of several areas. Traditionally, most physics students have followed the Physics program of study in Section III-A. Recently, however, there has been increased demand for people with an educational background that transcends traditional areas of specialization. More and more people study one field as an undergraduate and another as a graduate student, or have two areas of undergraduate concentration. They should consider the Applied Physics program in Section III-B.

A strength of the Colorado State University Physics Department is a friendly and informal relationship between students and faculty. The undergraduate study room and the Society of Physics Students bring together students with a common interest in physics. Physics undergraduates have invited nationally recognized guest speakers and have played a leading role in the annual Physics Bowl, and they often become involved in undergraduate research and the Little Shop of Physics. We hope that every physics student will get to know many of the faculty members and consult with them freely to understand concepts both inside and outside of the normal curriculum, and to plan for future employment or for graduate school.

All of the CSU Physics faculty member (Section VI) hold doctorate degrees and most are currently engaged in physics research in addition to their teaching. They collaborate on research projects with students, with each other, and with people from other departments, other institutions, and other countries. Some of the scientists from other institutions that work most closely with the Physics faculty have the title "Affiliate Faculty." Undergraduate Physics majors are strongly encouraged to participate in one or more research projects during their time at CSU. Many majors work on an original project as part of the curriculum, during a summer job, or while participating in the University Workstudy Program. This is arranged by mutual agreement of the student and faculty member and is usually initiated by the student.

Physics Majors are considered for the First-Year Physics Scholarship upon completion of PH142 and later may apply for other awards, such as the Alumni Scholarship and the Weber Scholarship. Applications are available in the Physics Department Office. The deadline for applications is during the first half of Fall semester; the exact date is given on the application form.

II. Requirements for the B.S. Degree in Physics

All physics majors are required to take a core set of courses in Physics, Chemistry, Mathematics, Computer Science, and Communications. In addition, to round out your curriculum, you will elect courses that fit your personal interests and long-term goals. there are also college-level and university-level breadth requirements that give your education greater diversity. The Physics Major Checklist in Section VII specifies these requirements in a convenient form. For those interested in the Applied Physics option, a list of approved Technical Electives follows the checklist in Section VII. Colorado State University Physics majors must achieve a minimum grade of C- in each course required under headings i, ii, and iv of the checklist. Substitutions for required courses can be made upon written approval of the Key Advisor. Waivers can be made only by the Department Chair.

Requirements for students transferring into the Physics major from other schools or from other departments at CSU are:

Complete PH141 (or its equivalent) with a grade of C- or better.
Complete M155 or M160 (or its equivalent) with a grade of C- or better.
Have a cumulative CSU GPA of at least 2.0.

For students transferring into Physics from other majors, the following substitutions are acceptable, upon advisor approval, if grades of C- or higher were obtained: EE201 for PH245, EE341 and EE342 for PH351, ME237 and ME337 for PH361. However, CE260, 261, 262 (Statics and Dynamics) are not considered substitutes for PH341 (Mechanics).

III. Suggested Programs of Study

In addition to having an overall plan through graduation, all Physics majors, including students having Physics as a second major, should plan their schedule each semester and then discuss it with their advisor from the Physics faculty. The following are suggested programs, but many students make rearrangements to fit their own needs, consistent with the minimum requirements enumerated in the Physics Major Checklist.

A. Physics Program

The Physics program is recommended for students who desire a traditional Physics degree and/or plan graduate study in physics.

Freshman Year
Fall		Spring
PH 141	(5) ____ Phys. Sci. Engr. I	PH 142	(4) ____ Phys. Sci. Engr. II
M 160	(4) ____ Calculus I	M 161	(4) ____ Calculus II
CO 150	(3) ____ Composition	CS 151	(4) ____ C++ Prog.
Breadth	(3) ____ _______________	Breadth	(3) ____ _______________
EX (PE)	(1) ____ _______________		16 credits
	16 credits
Sophomore Year
Fall		Spring
PH 193	(1) ____ Flying Circus Physics	PH 314	(4) ____ Modern Physics
PH 245	(3) ____ Electronics	PH 315	(2) ____ Modern Physics Lab
M 261	(4) ____ Calculus III	M 340	(4) ____ Differential Equations
C 111	(4) ____ General Chemistry I	Biol. Sci.	(3) ____ _______________
C 112	(1) ____ General Chemistry Lab I	Breadth	(3) ____ _______________
Breadth	(3) ____ _______________	EX (PE)	(1) ____ _______________
	16 credits		17 credits
Junior Year
Fall		Spring
PH 341	(4) ____ Mechanics	PH 351	(4) ____ Electricity & Magnetism
PH 353	(4) ____ Optics & Waves	PH 361	(3) ____ Thermodynamics
JT 300	(3) ____ Tech. Commun.	Math	(3) ____ _______________
Math	(3) ____ _______________	Unrestr.	(6) ____ _______________
Breadth	(3) ____ _______________		16 credits
	17 credits
Senior Year
Fall		Spring
PH 451	(3) ____ Intro. Quantum Mech. I	PH 325	(2) ____ Advanced Physics Lab
PH 462	(3) ____ Statistical Physics	PH 452	(3) ____ Intro. Quantum Mech. II
Technical	(3) ____ _______________	PH 492	(1) ____ Seminar
Unrestr.	(6) ____ _______________	Technical	(3) ____ _______________
	15 credits	Unrestr.	(6) ____ _______________
			15 credits

B. Applied Physics Program

The Applied Physics program is recommended for students who have specific interdisciplinary interests and/or plan graduate study in fields other than Physics. The suggested four-year schedule for this program differs from that for the Physics program only in the junior and senior years. The suggested schedule for these two years is as follows.

Junior Year
Fall		Spring
PH 341	(4) ____ Mechanics	PH 351	(4) ____ Electricity & Magnetism
PH 353	(4) ____ Optics & Waves	PH 361	(3) ____ Thermodynamics
JT 300	(3) ____ Tech. Commun.	Technical	(3) ____ _______________
Technical	(3) ____ _______________	Unrestr.	(6) ____ _______________
Breadth	(3) ____ _______________		16 credits
	17 credits
Senior Year
Fall		Spring
PH 451	(3) ____ Intro. Quantum Mech. I	PH 325	(2) ____ Advanced Physics Lab
Technical	(6) ____ _______________	PH 492	(1) ____ Seminar
Unrestr.	(6) ____ _______________	Technical	(6) ____ _______________
	15 credits	Unrestr.	(6) ____ _______________
			15 credits

IV. Minor in Physics

Students in other fields may find that courses in physics are valuable for their major. Hence, we offer a minor in Physics, with the requirements outlined in Section VIII.

V. Physics Department Courses

PH 110 03(3-0-0). Descriptive Physics. F, S, SS. Credit not allowed for both PH 110 and PH 121. Conceptual aspects of physics applied to phenomena in everyday life and to problems in other fields of science.

PH 111 01(2-0-0). Descriptive Physics Lab. F, S. Corequisite PH 110. Experiments dealing with basic physics concepts, including explorations of everyday phenomena.

PH 121 05(3-2-1). General Physics I. F, SS. Corequisite M 125. Credit not allowed for both PH 121 and PH 110; or for both PH 121 and PH 141. Concepts of force, torque, energy, momentum and work are used in covering topics of fluids, waves, sound, temperature and heat. Biological, physical examples. (Noncalculus.)

PH 122 05(3-2-1). General Physics II. S. Prerequisite: PH 121. Credit not allowed for both PH 122 and PH 142. Electricity, including electrostatics and simple circuits; magnetism; optics; aspects of nuclear physics and radiation. Biological, physical examples. (Noncalculus.)

PH 141 05(3-2-1). Physics for Scientists and Engineers I. F, S, SS. Prerequisite: M 126; M 155 or M 160. Students who have had high school physics may enroll in M 155 or M 160 concurrently. Credit not allowed for both PH 141 and PH 121. Forces, energy, momentum, angular momentum, oscillations, waves, heat, thermodynamics. (Calculus based.)

PH 142 05(3-2-1). Physics for Scientists and Engineers II. F, S. Prerequisite: PH 141, concurrent registration in M 161 or M 255. Credit not allowed for both PH 142 and PH 122. Electricity and magnetism, circuits, light, optics. (Calculus based.)

PH 193 01(1-0-0). Seminar--Flying Circus of Physics. F. Discussion of physics experienced in everyday life.

PH 245 03(2-3-0). Introduction to Electronics. F. Prerequisite: PH 142, M 161. AC circuits, physical bases and applications of electronic devices.

PH 298 Var [1-6]. Introductory Research. F, S, SS.

PH 314 04(4-0-0). Introduction to Modern Physics. S. Prerequisite: PH142, concurrent registration in M 261. Relativity; quantum mechanics; atomic structure; applications to solid-state, nuclear and elementary-particle physics.

PH 315 02(0-4-0). Modern Physics Laboratory. S. Corequisite: PH 314. Experiments in modern physics.

PH 325 02(0-4-0). Advanced Physics Laboratory. S. Prerequisite: PH315, concurrent registration in JT 300. Advanced experiments in electricity and magnetism, statistical physics and quantum mechanics.

PH 341 04(4-0-0). Mechanics. F. Prerequisite: PH 141, M 340. Particle dynamics, translation and rotation of rigid bodies, moving coordinate systems, Lagrangian mechanics, matrix and tensor methods.

PH 351 04(4-0-0). Electricity and Magnetism. S. Prerequisite: M 340, PH 142. Electrostatics, magnetostatics, currents, time-dependent electric and magnetic fields, radiation.

PH 353 04(3-3-0). Optics and Waves. Prerequisite: M 261, PH 141. Geometrical optics; wave optics; interference, diffraction and polarization; quantum optics.

PH 361 03(3-0-0). Physical Thermodynamics. S. Prerequisite: PH 142, M 261. Laws of thermodynamics; thermodynamic potentials; applications to topics such as fluids, phase transitions, electrical and magnetic systems and binary mixtures.

PH 384 Var [1-5]. Supervised College Teaching. F, S, SS. Prerequisite: PH 121 or PH 141, written consent of department head. Maximum of 10 credits allowed in course. Participation as a physics tutor.

PH 451 03(3-0-0). Introductory Quantum Mechanics I. F. Prerequisite: PH 314, M 340. Schrodinger's theory of wave mechanics, potential wells, harmonic oscillators, wave packets, operators, angular momentum.

PH 452 03(3-0-0). Introductory Quantum Mechanics II. S. Prerequisite: PH 451. Approximation techniques, perturbation theory, identical particles and spin, structure and spectra of atoms and molecules, hydrogen atom.

PH 462 03(3-0-0). Statistical Physics. F. Prerequisite: M 340, PH 314, PH 361. Maxwell-Boltzmann, Fermi-Dirac, and Bose-Einstein distribution functions; kinetic theory; applications to solids, metals, semiconductors and gases.

PH 492 01(0-0-1). Seminar. S. Students give seminars on selected modern topics.

PH 521 03(3-0-0). Introduction to Lasers. S. Prerequisite: M 340, PH 314 or C 477. Stimulated emission, laser resonators, theory of laser oscillation, specific laser systems, applications.

PH 522 01(0-2-0). Introductory Laser Spectroscopy. S. Corequisite: PH 521. Experiments providing hands-on experiences with lasers.

PH 531 03(3-0-0). Introductory Solid State Physics. S. Crystals, bonding, phonons, energy bands, semiconductors, optical properties, superconductivity, dielectric and magnetic properties.

PH 561 03(3-0-0). Particle Physics. S. Prerequisite: PH 314. Introduction to quark model, standard model and scattering models. Physics of e⁺ e^- and hadron colliders.

PH 571 03(3-0-0). Methods of Mathematical Physics I. F. Prerequisite: M 340. Vector and tensor analysis, matrices, calculus of variations, complex variables, calculus of residues, infinite series, integral transforms.

PH 572 03(3-0-0). Methods of Mathematical Physic II. S. Prerequisite: PH 571. Applications of partial differential equations, orthogonal functions, calculus of variations, Green's functions, integral transforms to physical problems.

AA 100 03(3-0-0). Introductory Astronomy. F, S, SS. Astronomical techniques, solar system, stars, and stellar systems. Evening viewing sessions with 16-inch reflecting telescope.

AA 101 01(0-2-0). Astronomy Laboratory. F, S, SS. Prerequisite: AA 100 or concurrent registration. Telescope and its use. Observation of moon, planets, stars, galaxies, and the Milky Way.

AA 150 03(2-3-0). Observational Astronomy. SS. Astronomical objects in the night and day sky; observation with 16-inch telescope.

AA 301 05(4-2-0). Astrophysics I. Prerequisite: M 124, M 126; PH 110 or PH 121 or PH 141. Celestial mechanics; earth-moon system; sun, planets and satellites; interplanetary medium; origin of the solar system.

AA 302 05(4-2-0). Astrophysics II. S. Prerequisite: M 124, M 126; PH 110 or PH 121 or PH 141. Properties of stars, variable stars, binary- and multiple-star systems, star clusters, interstellar medium, stellar evolution.

AA 303 05(4-2-0). Astrophysics III. F. Prerequisite: M 124, M 126; PH 110 or PH 121 or PH 141. Milky Way, galaxies, quasars, special and general relativity, cosmology.

AA 495 Var [1-6]. Independent Study in Astrophysics. F, S, SS.

VI. Physics Department Staff

Name and Rank	Degrees	Specialization
Faculty
R. Mark Bradley Professor	B.S., U. Toronto Ph.D., Stanford U.	Condensed-matter theory, Statistical mechanics
Roger B. Culver Professor	B.A., U. California Ph.D., Ohio State U.	Astronomy and astrophysics (experimental)
Richard D. Etters Professor	B.S., Oregon State U. Ph.D., Iowa State U.	Solid-state theory, Quantum fluids and solids
Richard E. Eykholt Assoc. Professor	B.S., U. California Ph.D., U. California	Nonlinear dynamics, Chaos, Mathematical physics
William M. Fairbank, Jr. Professor	B.S., Pomona College Ph.D., Stanford U.	Laser spectroscopy, Single-atom detection
Stuart B. Field Assoc. Professor	B.S., Stanford U. M.S., Ph.D., U. Chicago	Electron transport, Vortices in superconductors
Marshall Fixman U. Dist. Professor (Joint appointment with Department of Chemistry)	A.B., Washington U. Ph.D., MIT	Statistical mechanics, Polymer theory, Solid-state theory
Martin P. Gelfand Asst. Professor	B.A., U. Pennsylvania Ph.D., Cornell U.	Condensed matter theory
John L. Harton Asst. Professor	B.S., U. California--Davis Ph.D., MIT	Elementary-particle (experiment)
Hans D. Hochheimer Professor	B.S., Johann Wolfgang Goethe U. Ph.D., U. Regensburg	High-pressure studies of condensed-matter systems
Phillip D. Kearney Assoc. Professor	B.S., U. Michigan Ph.D., U. Michigan	Environmental radiation
Sanford Kern Assoc. Professor	B.S., Brooklyn College Ph.D., Purdue U.	Magnetism, Crystal fields, Neutron scattering
David A. Krueger Professor Key Advisor	B.S., Montana State U. Ph.D., U. Washington	Fluids, Laser remote sensing
Siu-Au Lee Professor	B.S., U. Wisconsin Ph.D., Stanford U.	Laser spectroscopy, Atom interferometry
Robert G. Leisure Professor	B.S., Western Kentucky U. Ph.D., Washington U.	Ultrasonic studies of condensed-matter systems
Stephen R. Lundeen Professor	B.S., Trinity College Ph.D., Harvard U.	Fast-beam laser-RF spectroscopy
Carl E. Patton Professor	B.S., MIT Ph.D., California Tech.	Magnetism and magnetic materials, Thin films, Microwave magnetics
John C. Raich Professor College Dean	B.S., Iowa State U. Ph.D., Iowa State U.	Molecular crystals
Raymond S. Robinson Assoc. Professor Assoc. Department Chair	B.S., Idaho State U. Ph.D., Colorado State U.	Ion beam/surface interactions, Electric space propulsion
Chaio-Yao She Professor	B.S., National Taiwan U. Ph.D., Stanford U.	Nonlinear optics, Laser atmospheric measurements
James R. Sites Professor Department Chair	B.S., Duke U. Ph.D., Cornell U.	Semiconductor physics, Thin-film solar cells
Walter H. Toki Professor	A.B., U. California--Berkeley Ph.D., MIT	Elementary-particle experiment
Robert J. Wilson Professor	B.S., U. London M.S., Ph.D., Purdue U.	Elementary-particle experiment
Laboratory Manager
Brian K. Jones	B.S., Case Western U. M.S., Cornell U.	Teaching innovations
Emeritus Faculty
Saul A. Basri Professor	B.S., MIT Ph.S., Columbia U.	Elementary-particle theory
William D. Derbyshire Assoc. Professor	M.E., Stevens Inst. Tech. Ph.D., Purdue U.	Magnetism theory
Lawrence N. Hadley Professor	B.S., Friends U. Ph.D., U. Michigan	Optical properties of thin films
Marvin W. Heller Assoc. Professor	B.A., Grinnell College Ph.D., Iowa State U.	Semiconductor physics
Harold R. Kaufman Professor	B.S., Northwestern U. Ph.D., Colorado State U.	Plasma physics, Ion propulsion
Dale R. Winder Assoc. Professor	A.B., DePauw U. Ph.D., Case Western U.	Crystal structure

Affiliate Faculty
Alan Bishop Los Alamos National Laboratory Los Alamos, NM 87545	Robert E. Camley University of Colorado Boulder, CO 80907	Eric Craine, Director Western Research Company Tucson, AZ 85719
Jerome J. Green Microwave Magnetics Lexington, MA 02173	Heinrich Roder Los Alamos National Laboratory Los Alamos, NM 87545	W. Greg Sturrus Youngstown State University Youngstown, OH 44555
Basil Swanson Los Alamos National Laboratory Los Alamos, NM 87545	H. Harry Weider University of California, San Diego San Diego, CA 92092

Office Staff		Technical Staff
Bonnie Gillmore	Staff Assistant	Wallace Akers	Instrument Maker
Sandy Demlow	Administrative Assistant	David Warner	Project Engineer
Marilyn Anderson	Administrative Assistant

VII. Physics Major Checklist

Fill in course, term, year, and number of credits; e.g., PH 141 (5) F99 for planned courses and then PH141 (5) (F99) after you have taken the course.

i. Physics (41 credits)
PH 141	(5) ____ Phys. Sci. Engr. I	PH 341	(4) ____ Mechanics
PH 142	(5) ____ Phys. Sci. Engr. II	PH 351	(4) ____ Electricity and Magnetism
PH 193	(1) ____ Flying Circus of Physics	PH 353	(4) ____ Optics & Waves
PH 245	(3) ____ Electronics	PH 361	(3) ____ Thermodynamics
PH 314	(4) ____ Modern Physics	PH 451	(3) ____ Intro. Quantum Mech. I
PH 315	(2) ____ Modern Physics Lab	PH 492	(1) ____ Seminar
PH 325	(2) ____ Advanced Physics Lab
ii. Related Courses (34 credits)
C 111	(4) ____ General Chemistry I	M 160	(4) ____ Calculus I
C 112	(4) ____ General Chemistry Lab I	M 161	(4) ____ Calculus II
CO 150	(3) ____ Composition	M 261	(4) ____ Calculus III
CS 151	(4) ____ C++ Programming	M 340	(4) ____ Differential Equations
JT 300	(3) ____ Technical Commun.	Biol. Sci.¹	(3) ____ _________________

iii. Breadth Requirements (17 credits)
The Arts²	(3) ________________	Social Sciences²	(3) ________________
Humanities²	(3) ________________	Diversities²	(3) ________________
History²	(3) ________________	Physical Education/Wellness³	(2) ________________

All undergraduates must take one Cross-Cultural Awareness course. See the Undergraduate Degree Requirements section of the General Catalog for a list of acceptable courses. Some choices will also satisfy one of the above Breadth Requirements.
____________________

¹ Select a course with a prefix of B, BC, BY, SC, or Z from the list in Category IIA of the Arts and Sciences core Curriculum, which appears in the College of Natural Sciences section of the General Catalog.

² Select a course from the appropriate list in Category II of the Art and Sciences Core Curriculum, which appears in the College of Natural Sciences section of the General Catalog.

³ Select two credits of coursework from the list is Category V of the University Studies Program, which appears in the Undergraduate Requirements section of the General Catalog.

iv. Additional Technical Requirements (18 credits)
Technical electives should be selected from the list on the following page to satisfy the requirements of one of the two Programs below.

a. Physics Program

PH 452 (3) ____ Intro. Quan. Mech. II

PH 462 (3) ____ Statistical Physics

Category 3 (6) ____ ________________ ____ ________________

Additional courses from Categories 1-7,
but not from the B lists (6)
____ ________________

____ ________________

b. Applied Physics Program

Categories 1-3, but not PH 193, 384, or 495 (3 credits) ____ ____________

From one of the Categories 4-7, including the B list (12 credits) (must include at lease 6 credits at the 300 level or above)

____ ____________ ____ ____________ ____ ____________ ____ ____________

Additional courses from Categories 1-7,
but not from the B lists (3 credits)
____ ____________

Limits for either program:

At most 1 credit of PH 193 in addition to that in Section i above

At most 2 credit of PH 384

It is strongly recommended, but not required, that students take at least 3 credits of:

PH 498 Research

and/or at least one of the following courses:

PH 521/522 Intro. to Lasers/Lab

PH 531 Intro. Solid State Physics

PH 561 Elem. Particle Physics

v. Unrestricted Electives (18 credits)

____ ____________ ____ ____________ ____ ____________ ____ ____________

Summary

You must have a total of at least 128 credits, with at least 45 credits at the 300 level or above.
You should have your advisor sign and date an approval of your choices in Section iv.
Any deviations from the above schedule must be explained in writing and signed and dated by your advisor.
You must have a grade of C- or better in courses used under headings i, ii and iv.

Technical Electives

These additional technical requirements form the distinction between the Physics and Applied Physics programs. The required credits must be chosen from the categories below subject to the restrictions indicated. If two courses have very similar content, they cannot both be counted. Other courses above 500, but below 600, may be used with advisor approval.

Category 1

PH 193 (1) Flying Circus of Physics

All PH courses above 300 and below 600

Category 2 (For each AA course, only 3 of the credits count as Technical Electives)

AA 301 (5) Astrophysics I C 113 (3) General Chemistry II

AA 302 (5) Astrophysics II C 114 (1) General Chemistry Lab II

AA 303 (5) Astrophysics III CE 300 (4) Fluid Mechanics

Category 3 (Math)

M 317 (4) Adv. Calculus One Variable M 400B (3) Topics--Fractals

M 331 (3) Meth. Applied Math I M 417 (3) Adv. Multivariable Calculus

M 332 (3) Meth. Applied Math II M 419 (3) Intro. Complex Variables

M 350 (4) Intro. Numerical Analysis I ST 309 (3) Engineering Statistics

M 351 (4) Intro. Numerical Analysis II ST 420 (3) Prob. & Math. Statistics I

M 369 (3) Linear Algebra ST 430 (3) Prob. Math. Statistics II

M 400A (3) Topics--Diff. Geom.

Category 4 (Electronics, Semiconductors, Optics)

List A List B

PH 521 (3) Intro. Lasers EE 311 (3) Linear System Analysis I

PH 522 (1) Intro. Lasers Lab EE 312 (3) Linear System Analysis II

PH 531 (3) Intro. Solid State Physics EE 372 (3) Physical Electronics

EE 331 (4) Electronics Principles I EE 411 (3) Control Systems

EE 332 (4) Electronic Principles II EE 412 (3) Digital Control & Filters

EE 471 (4) Semiconductor Devices EE 421 (3) Communication Systems

EE 472 (3) MOS Integrated Circuits

Category 5 (Computers)

List A List B

CS 200 (4) Algorithms & Data Structures CS 201 (4) Discrete Structures

CS 301 (4) Found. Computer Science CS 253 (4) Computer Prog. Languages

CS 314 (4) Software Develop. Meth. CS 370 (4) System Arch & Software

CS 410 (4) Intro. Computer Graphics CS 420 (4) Formal Lang. & Automata

CS 440 (4) Intro. Artificial Intelligence

CS 475 (4) Parallel Programming

M 460 (3) Info. Integrity and Security

Category 6 (Chemical Physics)

List A List B

C 245 (4) Org. & Biol. Chem. C 331 (3) Quantitative Analysis

C 246 (1) Org. & Biol. Chem. Lab C 332 (2) Quantitative Analysis Lab

C 261 (3) Basic Inorganic Chemistry C 334 (1) Quantitative Analysis Lab

C 341 (3) Organic Chemistry I C 440 (2) Adv. Organic Lab

C 343 (3) Organic Chemistry II C 461 (3) Inorganic Chemistry

C 344 (2) Organic Chemistry Lab C 462 (2) Inorganic Chemistry Lab

C 471 (4) Fund. Physical Chemistry

C 475 (3) Physical Chemistry I

C 477 (3) Physical Chemistry II

C 478 (2) Physical Chemistry Lab

C 480 (3) Physical Chemistry Eng.

Category 7 (Medical Physics)

List A List B

AY 550 (2) Transm. Electron Micr. AY 345 (4) Functional Neuroanatomy

AY 552 (2) Intro. Scanning EM AY 445 (3) Human Brain & Its Disorders

R 400 (3) Radioisotope Techniques AY 520 (5) Princ. Neural Science

R 530 (3) Radiol. Physics and Dos. I C 433 (3) Clinical Chemistry

PS 310 (3) Fund. Physiology

PS 432 (2) Radioimmunoassay

R 300 (3) Intro. Radiation Biology

R 532 (2) Nucl. Instr. & Measurements

R 550 (5) Princ. Radiation Biology

R 570 (2) Radioecology

Some of these courses have prerequisites which may be waived by the department offering the course (particularly if similar material has been covered in another course).

VIII. Physics Minor Checklist

Fill in course, term, year, and number of credits; e.g., PH 141 (5) F99 for planned courses and then PH 141 (5) (F99) after you have taken the course.

i. Required Physics Courses
PH 141	(5) ____ Phys. Sci. & Engr. I
PH 142	(5) ____ Phys. Sci. & Engr. II
PH 314	(4) ____ Intro. Modern Physics
ii. Additional Physics Courses (8 credits, including at least 5 credits of PH courses)
PH 315	(2) ____ Modern Physics Lab
PH 325	(2) ____ Adv. Physics Lab
PH 341	(4) ____ Mechanics
PH 351	(4) ____ Electricity & Magnetism
PH 353	(4) ____ Optics & Waves
PH 361	(3) ____ Thermodynamics
PH 451	(3) ____ Intro. Quantum Mech. I
PH 452	(3) ____ Intro. Quantum Mech. II
PH 462	(3) ____ Statistical Physics
AA 301	(5) ____ Astrophysics I
AA 302	(5) ____ Astrophysics II
AA 303	(5) ____ Astrophysics III

Substitutions require written approval by the Key Advisor in the Physics Department. The minimum grade of C- is required in all courses used for the minor in Physics.

The possibility of additional course work to complete prerequisites should be considered when planning your program.

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