Fred Gilman, Head
Office: Wean Hall 7325
Kunal Ghosh, Assistant
Head for Undergraduate Affairs
Hilary Homer, Student
Programs Coordinator
Student Programs Office:
Wean Hall 7319
World Wide Web: http://info.phys.cmu.edu/
Physics,
one of the basic sciences, has its origin in the irrepressible human
curiosity to explore and understand the natural world. This fundamental
urge to discover has led to the detailed understanding of a remarkable
variety of physical phenomena. Our knowledge now encompasses the
large-scale movement of galaxies, the minute motions within atoms and
nuclei, and the complex structure of
the assemblies of molecules which make life possible. The spectacular
enlargement of our comprehension of the physical world forms an
impressive part of the intellectual and cultural heritage of our times.
The opportunity to add
to this heritage is an important source of motivation for young
physicists.
The application of discoveries in physics to the solution of complex
modern
technological problems offers a vast field in which physicists also
make
decisive contributions. The interplay of pure and applied physics has
always
been fruitful and today ensures many rewarding career opportunities for
physics
students.
The undergraduate
curriculum in physics has been carefully designed to provide a firm
knowledge of the basic principles of physics, an appreciation of a wide
range of physical problems of current interest, and the capacity to
formulate and solve new problems. In addition to classwork and problem
solving, the curriculum includes the study of physical phenomena in the
laboratory. Physics students are strongly encouraged to go beyond the
formal theoretical and experimental course work and become involved in
research projects under the guidance of individual faculty members.
Students may choose from
a
variety of degree options:
• B.S. in Physics
• B.A. in Physics
• B.S. in Physics with
Tracks in:
- Applied Physics
- Astrophysics
- Biological Physics
- Chemical Physics
- Computational Physics
The objectives and
requirements for each of these options are described in the paragraphs
below. Each allows considerable latitude in the choice of electives.
Through the judicious
choice of elective courses, a double major program combining physics
and
another discipline can be readily achieved. A minor in physics is also
offered
for those students who major in other disciplines. The student, with
the
help of their faculty advisors, can easily build a program which aims
at
specific career objectives.
The Department maintains
an active and wide-ranging program of advising. Beyond aiding in
academic planning, Department advisors can also assist students in
finding research work during the academic year and technical jobs and
internships for the summer, as
well as planning and executing the necessary steps for gaining
employment
or continuing their studies beyond the bachelor's degree. Whether
students
follow a standard curriculum or not, the student should consult their
academic
advisor at least once every semester.
B.S. degree candidates
can
choose not only from a wide variety of intermediate and advanced topics
in
physics, but also from a range of material in other science or
engineering
fields. The B.S. degree serves as a solid foundation for students
wishing
to go on to graduate work in physics or in any of a large number of
fields
in pure or applied science or engineering, for which a sound grasp of
physics
and mathematics is essential. This program also provides excellent
preparation for careers in teaching, for work in industrial or
governmental research
and development, or for other employment in business or industry with a
significant scientific component.
Physics
Courses
Units
33-104 Experimental
Physics(1)
9
33-111 Physics I for
Science Students
12
or
33-131 Matter and
Interactions I
12
33-112 Physics II for
Science Students
12
or
33-132 Matter and Interactions II
12
33-201, 202, 301,
302, 401, 402 Colloquium
I
to VI (1 unit each)
6
33-211 Physics III:
Modern
Essentials
10
33-228 Electronics
10
33-231 Physical Analysis
9
33-232 Mathematical
Methods of Physics
9
33-234 Quantum Physics
10
33-331 Physical Mechanics
I
10
33-332 Physical Mechanics
II
10
33-340 Modern Physics
Laboratory
10
33-341 Thermal Physics I
10
33-338 Intermediate
Electricity and Magnetism I
10
33-439 Intermediate
Electricity and Magnetism II
10
Physics Electives - at
least 18 units(2),(3)
18
Minimum Total Physics
Units(4)
165
Mathematics
Courses
21-120 Differential and
Integral Calculus
10
21-122 Integration,
Differential Equations, and Approximation 10
21-259 Calculus in Three
Dimensions
9
Mathematics Elective (at
least 9 units) (5)
9
Total Mathematics Units(4)
38
Mellon
College
of Science Core(6)
03-121 Modern Biology
9
09-105 Introduction to
Modern Chemistry
10
15-100 Introductory/Intermediate Programming
10
99-101 Computing Skills
Workshop
3
Humanities,
Social Sciences, or Fine Arts Courses(4),(7)
72
Technical
Electives(4),(8)
27
Free electives(4),(9)
26
(1) Experimental Physics must be taken no later than
the fall semester of the sophomore year.
(2) Qualifying electives in physics are listed below.
(3) Students planning to undertake graduate study in
physics should consider taking Advanced Quantum Physics I and II
(33-445, 33-446).
(4) Any excess units earned in physics or mathematics
courses count towards the technical units, and excess technical or
H&SS/FA units count towards free elective units.
(5) Choosen from 21-228 or any 21-3xx or 21-4xx course
except 21-350.
(6) The MCS core courses may be taken in any order,
but
must be finished by the end of the junior year.
(7) Humanities, Social Sciences and Fine Arts
(H&SS/FA) requirements follow the Mellon College of Science
guidelines.
(8)Technical electives are any courses in MCS, SCS,
Statistics, and CIT.
(9) A free elective is any Carnegie Mellon course.
However, a maximum of 9 units of physical education and/or military
science may be taken as free electives.
Fall and
Spring
Units
33-350 Undergraduate
Research(10)
Var.
33-451 Senior Research(10)
9
33-458 Special Problems
in
Computational Physics
9
33-499 Supervised Reading(10)
Var.
Fall Only
33-224 Stars, Galaxies
and
the Universe
9
33-241 Introduction to
Computational Physics
9
33-441/03-439
Introduction
to Biophysics
9
33-445 Advanced Quantum
Physics I
9
33-453 Intermediate
Optics
12
33-467 Astrophysics of
Stars and the Galaxy
9
Spring Only
33-114 Physics of Musical
Sound(11)
9
33-342 Thermal Physics II
10
33-446 Advanced Quantum
Physics II
9
33-448 Introduction to
Solid State Physics
9
33-456 Advanced
Computational Physics
9
33-466 Extragalactic
Astrophysics and Cosmology
9
33-658 Quantum Computation
9
Fall Only
(Alternate Years)
33-650 General Relativity
(2002, 2004)
9
Spring Only
(Alternate Years)
33-444 Introduction to
Nuclear & Particle Physics (2003, 2005) 9
Graduate
Courses
33-755 Quantum Mechanics
I
12
33-756 Quantum Mechanics
II
12
33-759 Introduction to
Theoretical Physics
12
33-761 Classical
Electrodynamics I
12
33-762 Classical
Electrodynamics II
12
33-765 Statistical
Mechanics
12
33-777 Introductory
Astrophysics
12
33-779 Introduction to
Nuclear and Particle Physics
12
33-783 Theory of Solids I
12
Notes
(10) Only one of the three courses – 33-350 (at least 9
units), 33-451, and 33-499 – may be used as a qualifying physics
elective. Any exception to this rule needs prior approval from the
Department.
(11) Prior approval from the Department is needed for
33-114 to be a qualifying elective.
First Year
Fall
Units
33-111 Physics I for
Science
Students
12
or
33-131 Matter and
Interactions I
12
15-100
Introductory/Intermediate Programming
10
21-120 Differential and
Integral Calculus
10
99-101 Computing Skills
Workshop
3
76-101 Interpretation and
Argument (MCS Core 1 of 8)
9
44
Spring
33-112 Physics II for
Science
Students
12
or
33-132 Matter and
Interactions II
12
33-104 Experimental
Physics
9
21-122 Integration,
Differential Equations, and Approximation 10
xx-xxx Humanities, Social
Sciences, or Fine Arts Course
(MCS Core 2 of 8)
9
40
Sophomore
Year
Fall
Units
33-211 Physics III:
Modern
Essentials
10
33-231 Physical Analysis
9
33-201 Undergraduate
Colloquium I
1
21-259 Calculus in Three
Dimensions
9
09-105 Introduction to
Modern Chemistry
10
xx-xxx H&SS/FA Course
(MCS Core 3 of 8)
9
48
Spring
33-228 Electronics
10
33-232 Mathematical
Methods of Physics
9
33-234 Quantum Physics
10
33-202 Undergraduate
Colloquium II
1
03-121 Modern Biology
9
xx-xxx H&SS/FA Course
(MCS Core 4 of 8)
9
48
Junior Year
Fall
Units
33-331 Physical Mechanics
I
10
33-338 Intermediate
Electricity and Magnetism I
10
33-341 Thermal Physics I
10
xx-xxx (Physics,
Technical, or Free) Elective (1 of 8)
9
33-301 Undergraduate
Colloquium III
1
xx-xxx H&SS/FA Course
(MCS Core 5 of 8)
9
48
Spring
33-332 Physical Mechanics
II
10
33-340 Modern Physics
Laboratory
10
33-439 Intermediate
Electricity and Magnetism II
10
xx-xxx (Physics,
Technical, or Free) Elective (2 of 8)
9
33-302 Undergraduate
Colloquium IV
1
xx-xxx H&SS/FA Course
(MCS Core 6 of 8)
9
49
Senior Year
Fall
Units
21-xxx Mathematics
Elective
9
xx-xxx (Physics,
Technical, or Free) Elective (3 of 8)
9
xx-xxx (Physics,
Technical, or Free) Elective (4 of 8)
9
xx-xxx (Physics,
Technical, or Free) Elective (5 of 8)
9
33-401 Undergraduate
Colloquium V
1
xx-xxx H&SS/FA Course
(MCS Core 7 of 8)
9
47
Spring
xx-xxx (Physics,
Technical, or Free) Elective (6 of 8)
9
xx-xxx (Physics,
Technical, or Free) Elective (7 of 8)
9
xx-xxx (Physics,
Technical, or Free) Elective (8 of 8)
8
33-402 Undergraduate
Colloquium VI
1
xx-xxx H&SS/FA Course
(MCS Core 8 of 8)
9
36
With fewer mathematics
and
technical elective requirements and more free electives, the B.A.
degree
offers an enhanced opportunity for students to combine the physics
degree
with intensive work in other non-technical areas.
The requirements for the
B.A. degree are the same as those listed above for the B.S. degree with
the following changes:
• No units of mathematics
elective are required
• No units of technical
electives are required
• Free electives now
account for 62 units.
The minimum number of
units required for this degree is 360.
With the extra units in
free electives, a student may, for example, double major with a
department in
the College of Humanities and Social Sciences, the College of Fine
Arts,
or Business Administration.
The B.S. in
Physics/Applied Physics Track is designed primarily for the student who
wants to prepare
for a career path that takes advantage of the diverse and expanding
opportunities for employment in industrial and government laboratories
with a B.S. degree. The program provides a solid foundation in the
concepts of physics, as well as giving the student the experience and
understanding of the application of these concepts.
The track is intended to
enhance computing and laboratory skills, and to introduce the
application of physics to those subjects of particular interest to the
student. Since the possible subject areas for study are so varied, the
track will be tailored to each student's needs within the framework
described below. To that end, the student
will first meet with the Track Advisor to discuss
interests and career goals and to choose computing, laboratory and
applications
electives which fulfill the requirements of the track.
The requirements for this
track are the same as those listed above for the B.S. degree with the
following changes:
Additions to
the requirements listed for the B.S. in Physics:
• 33-448 Introduction to
Solid State Physics
• One
course (at least 9 units) which strengthens the student's ability to
use the computer as a tool in the research environment
• Two courses (at least
18
units), at least one of them in another department, which broaden the
student's
laboratory skills
• Two courses (at least
18
units) in other departments which give the student experience in
applying
basic physics principles to a variety of problems
• One research course (at
least 9 units) - may be taken as either of the following two courses:
33-350 Undergraduate
Research
33-451 Senior Research.
The topic in the research
course must be in Applied Physics, to be approved by the Track Advisor.
(Under
special circumstances, research for pay may count toward this
requirement,
though it cannot be counted toward the units required for graduation.)
Modifications
from the requirements listed for the B.S. in Physics:
• 33-332 Physics
Mechanics
II is NOT required
• No units of Physics
Electives are required
• No units of Mathematics
Electives are required
• No units of Technical
Electives are required
The minimum number of
units required for this degree is 360.
The B.S. in
Physics/Astrophysics Track provides an option for those Physics majors
who either want to specialize in this subfield or plan careers in
astronomy or astrophysics. Career paths may include postgraduate
training in astronomy or astrophysics or proceeding directly to jobs in
these fields. The program provides a thorough foundation in the core
physics program with electives concentrating in astrophysics.
The requirements for this
track are the same as those listed above for the B.S. degree with the
following changes:
Additions to
the requirements listed for the B.S. in Physics:
• 33-224 Stars, Galaxies
and the Universe
• 33-467 Astrophysics of
Stars and the Galaxy
• 33-466 Extragalactic
Astrophysics and Cosmology
• One research course (at
least 9 units) - may be taken as either of the following two courses:
33-350 Undergraduate
Research
33-451 Senior Research
The topic in the research
course must be in Astrophysics, to be approved by the Track Advisor.
(Under special circumstances, research for pay may count toward this
requirement, though it cannot be counted toward the units required for
graduation.)
Modificationss
from the requirements listed for the B.S. in Physics:
• No units of Physics
Electives are required
• Only 9 units of
Technical Electives are required
The minimum number of
units required for this degree is 360.
The B.S. in
Physics/Biological Physics Track combines a rigorous foundation in
undergraduate physics with courses in Biological Physics and Chemistry.
It is particularly suitable
for students preparing for post-baccalaureate careers in the expanding
areas
of biological and medical physics or for graduate study in biophysics.
The
program is sufficiently flexible that it can be readily adapted to the
requirements of individual students. To that end, the student will
first meet with the Track Advisor to discuss interests and career goals
and to choose electives which fulfill the requirements of the track.
The Biological Physics
Track incorporates a number of courses which are also requirements for
the pre-medical program. Students interested in both the Biological
Physics Track and the pre-medical program should consult both with the
Track Advisor in the Physics Department and the Director of the Health
Professions Program for help in planning their programs.
The requirements for this
track are the same as those listed above for the B.S. degree with the
following changes:
Additions to
the requirements listed for the B.S. in Physics:
• 33-441/03-439
Introduction to Biophysics
• 03-231 Biochemistry I
• 09-217 Organic
Chemistry
I
• Two courses (at least
18
units) from the following list:
03-124 Modern Biology
Laboratory
03-130 Biology of
Organisms or 42-500 Physiology
03-232 Biochemistry II
03-438 Physical
Biochemistry
03-533 NMR in Biomedical
Sciences
03-534 Biological Imaging
and Fluorescence Spectroscopy
Modifications
from the requirements listed for the B.S. in Physics:
• 33-332 Physics
Mechanics
II is NOT required
• Only 9 units of Physics
Electives are required
• No units of Technical
Electives are required
The minimum number of
units required for this degree is 360.
The B.S. in
Physics/Chemical Physics Track is designed for students wishing to have
a strong grounding in physics along with a specialization in physical
chemistry and/or chemical physics. It is particularly suitable for
those students planning on graduate school in physics with an emphasis
on chemical physics or chemistry. The
program is sufficiently flexible that it can readily be adapted to the
requirements of individual students. To that end, the student will
first meet with the Track Advisor to discuss interests and career goals
and to choose electives which fulfill the requirements of the track.
The Chemical Physics
Track
incorporates a number of courses which are also requirements for the
pre-medical
program. Students interested in both the Chemical Physics Track and the
pre-medical program should consult both with their Physics Department
advisor and the Director of the Health Professions Program for help in
planning their programs.
The requirements for this
track are the same as those listed above for the B.S. degree with the
following changes:
Additions to
the requirements listed for the B.S. in Physics:
• 09-106 Modern Chemistry
II
• 09-344 Physical
Chemistry I (Quantum)
• 09-345 Physical
Chemistry II (Thermodynamics)
• Three courses (at least
27 units) from the following list:
09-217 Organic Chemistry
I
09-218 Organic Chemistry
II
09-221 Laboratory I:
Introduction to Chemical Analysis
09-322 Laboratory IV:
Molecular Spectroscopy and Dynamics
09-348 Inorganic
Chemistry
09-441 Nuclear and
Radiochemistry
09-445 Undergraduate
Research (9-12 units)
09-509 Physical Chemistry
of Macromolecules
09-511 Solid State
Materials Chemistry
Modifications
from the requirements listed for the B.S. in Physics:
• 33-332 Physics
Mechanics
II is NOT required
• No units of Physics
Electives are required
• No units of Technical
Electives are required
The minimum number of
units required for this degree is 360.
The B.S. in
Physics/Computational Physics Track is intended to fill the increasing
demand for physics graduates who are skilled in computational and
numerical techniques which are used
in the analysis of physical problems and in subjects ranging from
control
and real-time programming to software engineering and compiler and
operating
systems design. The degree provides the student with a rigorous
grounding
in physics as well as in the foundations and practice of computer use
as
applied to scientific problems. Work is done on machines ranging from
high level workstations through supercomputers.
The degree program
includes additional courses from the Mathematics and Computer Science
Departments
as well as special courses in computational physics from the Physics
Department. . The program is sufficiently flexible that it can be
readily adapted to
the requirements of individual students. To that end, the student will
first
meet with the Track Advisor to discuss interests and career goals and
to
choose electives which fulfill the requirements of the track.
The requirements for this
track are the same as those listed above for the B.S. degree with the
following changes:
Additions to
the requirements listed for the B.S. in Physics:
• 33-241 Introduction to
Computational Physics
• 33-456 Advanced
Computational Physics
• 21-127 Concepts of
Mathematics
• 21-369 Numerical Methods
• 15-211 Fundamental Data
Structures and Algorithms
• 15-212 Principles of
Programming
Modifications
from the requirements listed for the B.S. in Physics:
• No units of Physics
Electives are required
• No units of Mathematics
Electives are required
• No units of Technical
Electives are required
• Only 20 units of Free
Electives are required
The minimum number of units required for this degree is 360.
A
Double Major or a Dual Degree in Physics with the Primary Degree in
another Department
Physics may be taken as a
second major or for a second degree, with another department granting
the primary degree. The rules of the Physics Department for these two
options are distinct, as discussed below.
For Physics as a Double
Major with a B.S. or B.A. (alone or with any track), all requirements
of the degree and track as a primary major must be fulfilled except:
• No units of Mathematics
Elective are required
• No units of Technical
Electives are required
• No units of Free
Electives are required
• No H&SS/FA courses
are required
• The following courses
in
the MCS core are not required: 03-121, 09-105, 99-101.
However, 15-100 is required.
In order to receive a
Dual
Degree in physics with a first degree in another home department, all requirements for the particular physics track must be
fulfilled.
The non-technical requirements will be waived if the home department
has
a similar set of required courses. Also, the number of units required
is
90 more than the total units required by the department requiring the
fewer
total units.
The Minor in Physics is
designed to provide a solid foundation in physics at the introductory
level, followed by elective courses in which the student will become
familiar with a sample of the many modern areas of physics, and the
concepts and techniques employed therein. The sequence consists of two
introductory level courses followed by five electives chosen from the
list below. The choice of electives requires prior approval by the
Department of Physics, and should be made in close
consultation with the Physics Department faculty advisor. The
Department
intends to be flexible and accommodate the student's specific
interests.
The minor is open to all students of the university, although students
with
non-calculus based majors should be aware of the mathematics
requirements
for many physics courses (21-120, 122, 259).
The Physics minor
requires
7 courses of at least 9 units each, of which four are required and
three
are electives.
Required
Courses
I. Introductory
Physics I
Choose one
course:
33-106 Physics for
Engineering Students I
33-111 Physics for
Science
Students I
33-131 Matter and
Interactions I
II. Introductory
Physics II
Choose one
course:
33-107 Physics for
Engineering Students II
33-112 Physics for
Science
Students II
33-132 Matter and
Interactions II
III.
Modern Physics
33-211 Physics III:
Modern
Essentials
IV. Laboratory
Experience
33-104 Experimental
Physics
Elective
Courses
Choose three
courses from among the following list:
33-114 Physics of Musical
Sound
33-224 Stars, Galaxies
and
the Universe
33-225 Quantum Physics
and
Structure of Matter
33-228 Electronics
33-231 Physical Analysis
33-232 Mathematical
Methods of Physics
33-234 Quantum Physics
33-241 Introduction to
Computational Physics
33-331 Physical Mechanics
I
33-332 Physical Mechanics
II
33-338 Intermediate
Electricity and Magnetism I
33-340 Modern Physics
Laboratory
33-341 Thermal Physics I
33-342 Thermal Physics II
33-350 Undergraduate
Research
33-439 Intermediate
Electricity and Magnetism II
33-444 Introduction to
Nuclear & Particle Physics
33-445 Advanced Quantum
Physics I
33-446 Advanced Quantum
Physics II
33-448 Introduction to
Solid State Physics
33-451 Senior Research
33-453 Intermediate
Optics
33-456 Advanced
Computational Physics
33-458 Special Problems
in
Computational Physics
33-466 Astrophysics of
Stars and the Galaxy
33-467 Extragalactic
Astrophysics and Cosmology
33-650 General Relativity
33-658 Quantum Computation
Any one course from among
33-350 Undergraduate
Research
33-451 Senior Research
33-499 Supervised Reading
Any substitution of these requirements for the minor must be pre-approved in writing by the Physics Department.
ROY A. BRIERE, Assistant
Professor of Physics — Ph.D., University of Chicago; Carnegie Mellon,
1999—.
RUPERT CROFT, Assistant Professor of Physics — Ph.D., Oxford
University; Carnegie Mellon, 2001—.
TIZIANA DIMATTEO, Assistant
Professor of Physics — Ph.D., University of Cambridge; Carnegie
Mellon, 2004—.
RANDALL M. FEENSTRA, Professor of Physics —
Ph.D., California Institute of Technology; Carnegie Mellon,
1995—.
THOMAS A. FERGUSON,
Professor of Physics — Ph.D., University of California at Los Angeles;
Carnegie Mellon, 1985—.
GREGG B. FRANKLIN,
Professor of Physics, Associate Dean for Graduate Affairs, Mellon
College of Science — Ph.D., Massachusetts Institute of Technology;
Carnegie Mellon, 1984—.
STEPHEN GAROFF, Professor
of Physics — Ph.D., Harvard University; Carnegie Mellon, 1988—.
KUNAL
GHOSH, Principal Lecturer, Assistant Head for Undergraduate Affairs,
Department
of Physics — Ph.D., Iowa State University; Carnegie Mellon, 2001.
FREDERICK
J. GILMAN, Buhl Professor of Physics, Head, Department of Physics —
Ph.D., Princeton University; Carnegie Mellon, 1995—.
RICHARD E. GRIFFITHS,
Professor of Physics — Ph.D., University of Leicester, U.K.; Carnegie
Mellon, 1996—.
ROBERT B. GRIFFITHS,
University Professor & Otto Stern Professor of Physics — Ph.D.,
Stanford University; Carnegie Mellon, 1964—.
RICHARD F. HOLMAN,
Professor of Physics — Ph.D., Johns Hopkins University; Carnegie
Mellon, 1987—.
LEONARD S. KISSLINGER,
Professor of Physics — Ph.D., Indiana University; Carnegie Mellon,
1969—.
GEORGE KLEIN, Senior
Lecturer — Ph.D., New York University; Carnegie Mellon, 1993—.
MICHAEL J. LEVINE,
Professor of Physics — Ph.D., California Institute of Technology;
Carnegie Mellon,
1968—.
LING-FONG LI, Professor
of
Physics — Ph.D., University of Pennsylvania; Carnegie Mellon, 1974—.
BARRY B. LUOKKALA,
Principal Lecturer — Ph.D., Carnegie Mellon University; Carnegie
Mellon, 1990—.
SARA A. MAJETICH,
Professor of Physics — Ph.D., University of Georgia; Carnegie Mellon,
1990—.
CURTIS A. MEYER,
Professor
of Physics — Ph.D., University of California, Berkeley; Carnegie
Mellon,
1993—.
COLIN J. MORNINGSTAR,
Assistant Professor of Physics — Ph.D., University of Toronto; Carnegie
Mellon, 2000.
JOHN F. NAGLE, Professor
of Physics and Biological Sciences — Ph.D., Yale University; Carnegie
Mellon, 1967—.
JEFFREY B. PETERSON,
Associate Professor of Physics — Ph.D., University of California,
Berkeley; Carnegie Mellon, 1993—.
BRIAN P. QUINN, Professor
of Physics — Ph.D., Massachusetts Institute of Technology; Carnegie
Mellon,
l988—.
JAMES S. RUSS, Professor
of Physics — Ph.D., Princeton University; Carnegie Mellon, 1967—.
REINHARD A. SCHUMACHER,
Professor of Physics — Ph.D., Massachusetts Institute of Technology;
Carnegie Mellon, 1987—.
ROBERT F. SEKERKA,
University Professor of Physics and Mathematics — Ph.D., Harvard
University; Carnegie Mellon, 1969—.
ROBERT M. SUTER,
Professor
of Physics — Ph.D., Clark University; Carnegie Mellon, 1981—.
ROBERT H. SWENDSEN,
Professor of Physics, — Ph.D., University of Pennsylvania; Carnegie
Mellon, 1984—.
STEPHANIE TRISTRAM-NAGLE,
Senior Research Biologist — Ph.D., University of California, Berkeley;
Carnegie
Mellon, 1982—.
HELMUT VOGEL, Professor
of
Physics — Ph.D., University of Erlangen-Nuremberg; Carnegie Mellon,
1983—.
MICHAEL WIDOM, Professor
of Physics — Ph.D., University of Chicago; Carnegie Mellon, 1985—.
LUC BERGER, Professor
Emeritus of Physics — Ph.D., University of Lausanne, Switzerland;
Carnegie Mellon, 1960—.
RICHARD M. EDELSTEIN,
Professor Emeritus of Physics — Ph.D., Columbia University; Carnegie
Mellon, 1960—.
ARNOLD ENGLER, Professor
Emeritus of Physics — Ph.D., University of Berne, Switzerland; Carnegie
Mellon, 1962—.
JOHN G. FETKOVICH,
Professor Emeritus of Physics — Ph.D., Carnegie Mellon University;
Carnegie Mellon, 1959—.
SIMEON A. FRIEDBERG,
Professor Emeritus of Physics — D.Sc., Carnegie Institute of
Technology; Carnegie
Mellon, 1953—.
TRUMAN KOHMAN, Adjunct
Emeritus Professor of Physics — PhD.,
Carnegie Mellon, 1943 —.
ROBERT W. KRAEMER, Professor Emeritus of
Physics — Ph.D., Johns Hopkins University; Carnegie Mellon, 1965—.
JOHN A. RAYNE, Professor Emeritus of Physics —
Ph.D., University of Chicago; Carnegie Mellon, 1963—.
ROBERT T. SCHUMACHER,
Professor Emeritus of Physics — Ph.D., University of Illinois; Carnegie
Mellon, 1955-.
RAYMOND A. SORENSEN,
Professor Emeritus of Physics — Ph.D., Carnegie Mellon University;
Carnegie Mellon, 1961—.
NED S. VANDER VEN,
Professor Emeritus of Physics — Ph.D., Princeton University; Carnegie
Mellon, 1961—.
LINCOLN WOLFENSTEIN,
University Professor Emeritus of Physics — Ph.D., University of
Chicago; Carnegie Mellon, 1948—.
HUGH D. YOUNG, Professor
of Physics — Ph.D., Carnegie Mellon University; Carnegie Mellon, 1956—.
SHELLEY ANNA, Assistant
Professor of Chemical Engineering —
PhD., Harvard University; Carnegie Mellon, 2003 —.
DAVID GREVE, Professor, Electrical and
Computer Engineering — Ph.D., Lehigh University; Carnegie Mellon, 1982—.
MORTON KAPLAN, Professor,
Chemistry — Ph.D., Massachusetts Institute of Technology; Carnegie
Mellon, 1970—.
MICHAEL E. McHENRY, Professor, Materials Science and Engineering —
Ph.D., Massachusetts Institute of Technology; Carnegie Mellon, 1989—.
BENIOT MOREL, Senior Lecturer, Engineering and Public Policy — PhD. University of Geneva, Switzerland; Carnegie Mellon, 1987—.
ROBERT WHITE, Director,
Data Storage Systems Center, Electrical and Computer Engineering —
Ph.D., Stanford University; Carnegie Mellon, 1993—.
Jian-Gang ZHOU, Professor of Electrical and Computer Engineering — Ph.D., University of California San Diego; Carnegie Mellon, 1997—.