2010-11 Catalog | Caltech Academic Catalog

Ph 1 abc

Classical Mechanics and Electromagnetism

9 units (4-0-5) | first, second, third terms

The first year of a two-year course in introductory classical and modern physics. Topics: Newtonian mechanics in Ph 1 a; electricity and magnetism, and special relativity, in Ph 1 b, c. Emphasis on physical insight and problem solving. Ph 1 b, c is divided into two tracks: the Practical Track emphasizing practical electricity, and the Analytic Track, which teaches and uses methods of multivariable calculus. Students enrolled in the Practical Track are encouraged to take Ph 8 bc concurrently. Students will be given information helping them to choose a track at the end of fall term.

Instructors: Zmuidzinas, Harrison, Politzer, Filippone

Ph 2 ab

Waves, Quantum Mechanics, and Statistical Physics

9 units (4-0-5) | first, second terms

Prerequisites: Ph 1 abc, Ma 1 abc, or equivalents.

The second year of a five-term introductory course in classical and modern physics. Topics to be covered include waves and introductory quantum mechanics first term, statistical physics second term.

Instructors: Martin, Adhikari, Filippone

Ph 3

Physics Laboratory

6 units | first, second, third terms

Prerequisites: Ph 1 a or instructor's permission.

An introduction to experimental technique, commonly used in the physical sciences. A variety of topics is presented, including the Maxwell top, electrical and mechanical resonant systems, and radioactivity. Special emphasis is given to data analysis techniques based on modern statistical methods. The course consists of one three-hour laboratory session a week, conferences with the instructor, prelaboratory preparation, and analysis of experimental results. Graded pass/fail; seniors receive letter grades. Only one term may be taken for credit.

Instructors: Sannibale, Libbrecht

Ph 5

Physics Laboratory

9 units | first term

Prerequisites: Ph 1 abc, Ph 3, or equivalents.

A laboratory course dealing with "operational'' electronics with emphasis on analog electronics. The following topics are studied: RC circuits, electrical oscillations, operational amplifiers, diodes, and transistors. Combining diodes, transistors, and operational amplifiers; computer data acquisitions. The course culminates in a two-week project of the student's choosing.

Instructors: Rice, Sannibale, Libbrecht

Ph 6

Physics Laboratory

9 units | second term

Prerequisites: Ph 1 abc, Ph 2 b or Ph 12 b (or taken concurrently), and Ph 3 or equivalent.

Experiments in electromagnetic phenomena such as electromagnetic induction, properties of magnetic materials, and high-frequency circuits. Mobility of ions in gases; precise measurement of the value of e/m of the electron.

Instructors: Rice, Libbrecht

Ph 7

Physics Laboratory

9 units | third term

Prerequisites: Ph 6 or equivalent.

Experiments in atomic and nuclear physics, including studies of the Balmer series of hydrogen and deuterium, the decay of radio- active nuclei, absorption of X rays and gamma rays, ratios of abun-dances of isotopes, and the Stern-Gerlach experiment.

Instructors: Rice, Libbrecht

Ph 8 bc

Experiments in Electromagnetism

3 units (0-3-0) | second, third terms

Prerequisites: Ph 1 a.

A two-term sequence of experiments that parallel the material of Ph 1 bc. It includes measuring the force between wires with a homemade analytical balance, measuring properties of a 1,000-volt spark, and building and studying a radio-wave transmitter and receiver. The take-home experiments are constructed from a kit of tools and electronic parts. Measurements are compared to theoretical expectations.

Instructor: Pine

Ph 10

Frontiers in Physics

3 units (2-0-1) | first term

Prerequisites: Open for credit to freshmen and sophomores.

Weekly seminar by a member of the physics department or a visitor, to discuss his or her research at an introductory level; the other class meetings will be used to explore background material related to seminar topics and to answer questions that arise. The course will also help students find faculty sponsors for individual research projects. Graded pass/fail.

Instructor: Prince

Ph 11 abc

Research Tutorial

6 units (2-0-4) | second and third terms of freshman year and first term of sophomore year

A small number of students will be offered the opportunity to enroll in this tutorial, the purpose of which is to demonstrate how research ideas arise, and are evaluated and tested, and how those ideas that survive are developed. This is accomplished by doing individual, original projects. There will be weekly group meetings and individual tutorial meetings with the instructor. Support for summer research at Caltech between the freshman and sophomore years will be automatic for those students making satisfactory progress. Graded pass/fail.

Instructor: Tombrello

Ph 12 abc

Waves, Quantum Physics, and Statistical Mechanics

9 units (4-0-5) | first, second, third terms

Prerequisites: Ph 1 abc, Ma 1 abc, or equivalents.

A one-year course primarily for students intending further work in the physics option. Topics include classical waves; wave mechanics, interpretation of the quantum wave-function, one-dimensional bound states, scattering, and tunneling; thermodynamics, introductory kinetic theory, and quantum statistics.

Instructors: Kimble, Refael, Preskill

Ph 20, 21,

Computational Physics Laboratory

A series of courses on the application of computational techniques to simulate or solve simple physical systems, with the intent of aiding both physics understanding and programming ability. 20. 6 units (0-6-0); first, second, third terms. Introduction to scientific computing with applications to physics. Use of numerical algorithms and symbolic manipulation packages for solution of physical problems. Numerical integration and numerical solution of differential equations of motion. Simulation of orbital mechanics. 21. 6 units (0-6-0); second, third terms. Prerequisite: Ph 20 or equivalent experience with programming and numerical techniques. Introduction to numerical algorithms for scientific computing. Root-finding, Runge-Kutta methods, Monte Carlo techniques, numerical solution of partial differential equations, minimization techniques such as neural networks. Applications to problems in classical mechanics and discrete- element electromagnetism. 22. 6 units (0-6-0); third term. Prerequisite: Ph 20 or equivalent experience with programming and numerical techniques. Introduction to scientific computing on parallel computers. Introduction to parallel computing and multiprocessing. Message passing on networked workstations. Algorithm decomposition and parallelization. Numerical solution of N-body systems on multiprocessor computers.

Instructors: Mach, Prince

Ph 50 abc

Caltech Physics League

4 units (1-0-3) | first, second, third terms

Prerequisites: Ph 1 abc.

This course serves as a physics club, meeting weekly to discuss and analyze real-world problems in the physical sciences. A broad range of topics will be considered, such as energy production, space and atmospheric phenomena, astrophysics, nano-science, and others. Students will use basic physics knowledge to produce simplified (and perhaps speculative) models of complex natural phenomena. In addition to regular assignments, students will also compete in solving challenge problems each quarter, with prizes given in recognition of the best solutions.

Instructor: Refael

Ph 70

Oral and Written Communication

6 units (2-0-4) | second, third terms

Provides practice and guidance in oral and written communication of material related to contemporary physics research. Students will choose a topic of interest, make presentations of this material in a variety of formats, and, through a guided process, draft and revise a technical or review article on the topic. The course is intended for senior physics majors. Fulfills the Institute scientific writing requirement.

Instructor: Hitlin

Ph 77 abc

Advanced Physics Laboratory

9 units (0-5-4) | first, second, third terms

Prerequisites: Ph 7 or instructor's permission.

A three-term laboratory course to familiarize students with equipment and procedures used in the research laboratory. Experiments illustrate fundamental physical phenomena in atomic, optical, condensed-matter, nuclear, and particle physics, including NMR, laser-based atomic spectroscopy, gamma and X-ray spectroscopy, muon decay, weak localization, superconductivity, positron annihilation, and others.

Instructors: Black, Libbrecht

Ph 78 abc

Senior Thesis, Experimental

9 units | first, second, third terms

Prerequisites: To register for this course, the student must obtain approval of the chair of the Physics Undergraduate Committee (Ed Stone). Open only to senior physics majors.

This research must be supervised by a faculty member, the student's thesis adviser. Laboratory work is required for this course. Two 15-minute presentations to the Physics Undergraduate Committee are required, one at the end of the first term and the second at the midterm week of the third term. The written thesis must be completed and distributed to the committee one week before the second presentation. Not offered on a pass/fail basis. Note: Students wishing assistance in finding an adviser and/or a topic for a senior thesis are invited to consult with the chair of the Physics Undergraduate Committee, or any other member of this committee. A grade will not be assigned in Ph 78 or Ph 79 until the end of the third term. P grades will be given the first two terms, and then changed at the end of the course to the appropriate letter grade.

Ph 79 abc

Senior Thesis, Theoretical

9 units | first, second, third terms

Prerequisites: To register for this course, the student must obtain approval of the chair of the Physics Undergraduate Committee (Ed Stone). Open only to senior physics majors.

This research must be supervised by a faculty member, your thesis adviser. Two 15-minute presentations to the Physics Undergraduate Committee are required, one at the end of the first term and the second at the midterm week of the third term. The written thesis must be completed and distributed to the committee one week before the second presentation. Not offered on a pass/fail basis. Note: Students wishing assistance in finding an adviser and/or a topic for a senior thesis are invited to consult with the chair of the Physics Undergraduate Committee, or any other member of this committee. A grade will not be assigned in Ph 78 or Ph 79 until the end of the third term. P grades will be given the first two terms, and then changed at the end of the course to the appropriate letter grade.

Ph 101

Order-of-Magnitude Physics

9 units (3-0-6) | first term

Emphasis will be on using basic physics to understand complicated systems. Examples will be selected from properties of materials, geophysics, weather, planetary science, astrophysics, cosmology, biomechanics, etc.

Instructor: Phinney

Ph 103 ab

Topics in Contemporary Physics

9 units (3-0-6) | first, second terms

Prerequisites: instructor's permission.

A series of introductory one-term, independent courses. Students may register for any particular term or terms. a. Atomic and Molecular Spectroscopy. Second term. This course will review the basic spectroscopy of atoms and molecules, with applications to astrophysics, the terrestrial atmosphere, and the laboratory. Species to be discussed include hydrogen and simple multielectron atoms such as carbon, diatomic and polyatomic molecules, and some solids. Mechanisms and effects determining linewidths and lineshapes will be discussed for laboratory, atmospheric, and astrophysical conditions. Instructor: Phillips. Ph/Bi 103 b. Neuroscience for Physicists and Engineers. First term. A reading and discussion course on topics ranging from the function of single neurons to methods for studying multineural activity in synapses; electrical recording; vision; positron and NMR topography; and neural modeling. Preference is given to physics seniors. Instructor: Pine.

Ay/Ph 104

Relativistic Astrophysics

9 units (3-0-6) | third term

Prerequisites: Ph 1, Ph 2 ab.

This course is designed primarily for junior and senior undergraduates in astrophysics and physics. It covers the physics of black holes and neutron stars, including accretion, particle acceleration and gravitational waves, as well as their observable consequenes: (neutron stars) pulsars, magnetars, X-ray binaries, gamma-ray bursts, gravity wave sources; (black holes) X-ray transients, quasars/active galaxies, and sources of low-frequency gravitatonal waves.

Ph 105

Analog Electronics for Physicists

9 units | first term

Prerequisites: Ph 1 abc, Ph 3, or equivalents (the take-home lab of Ph 1 bc may be substituted for Ph 3).

A laboratory course dealing with "operational'' electronics with emphasis on analog electronics. The following topics are studied: RC circuits, electrical oscillations, operational amplifiers, diodes, and transistors. Combining diodes, transistors, and operational amplifiers; computer data acquisition. The course culminates in a two-week project of the student's choosing.

Instructors: Rice, Sannibale, Libbrecht

Ph 106 abc

Topics in Classical Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 2 ab or Ph 12 abc, Ma 2.

An intermediate course in the application of basic principles of classical physics to a wide variety of subjects. Roughly half of the year will be devoted to mechanics, and half to electromagnetism. Topics include Lagrangian and Hamiltonian formulations of mechanics, small oscillations and normal modes, boundary-value problems, multipole expansions, and various applications of electromagnetic theory.

Instructors: Cross, Eisenstein

APh/Ph 115 ab

Physics of Transport in Fluids

9 units (3-0-6) | first, second terms

Prerequisites: ACM 95 or equivalent.

There is growing interest in micro- and nanodevices in which a solid surface is made to contact a fluid for the purpose of measurement or actuation. Such devices include oscillating cantilevers, microfluidic arrays, optofluidic devices, and biofluidic sensors, to name a few. This course provides a self-contained treatment of the fundamentals of transport phenomena necessary for the development of such applications. Topics to include creeping and pulsatile flows, self-similar phenomena, lubrication and free surface flows, oscillating bubbles, spreading films, convective-diffusion processes, and instabilities leading to pattern formation. The first term will focus on fluid dynamical principles; the second term will examine processes triggered by thermal or concentration gradients.

Instructor: Troian

Ph/EE 118

Low-Noise Electronic Measurement

9 units (3-0-6) | second term

Prerequisites: Ph 105 or equivalent.

An introduction to ultralow-noise electrical measurements and sensor technology as applied to experimental research. Topics include physical noise processes, signal transduction, synchronous and lock-in detection, digital signal transforms, and other aspects of precision measurements. Specific sensor technologies will include SQUID sensors, single electron transistors, transition-edge sensors, tunnel junction detectors, micro- and nanomechanical detectors, and biosensors.

Instructor: Roukes

Ph 125 abc

Quantum Mechanics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ma 2 ab, Ph 12 abc or Ph 2 ab, or equivalents.

A one-year course in quantum mechanics and its applications, for students who have completed Ph 12 or Ph 2. Wave mechanics in 3-D, scattering theory, Hilbert spaces, matrix mechanics, angular momentum, symmetries, spin-1/2 systems, approximation methods, identical particles, and selected topics in atomic, solid-state, nuclear, and particle physics.

Instructor: Wise

Ph 127 abc

Statistical Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 12 c or equivalent, and a basic understanding of quantum and classical mechanics.

A course in the fundamental ideas and applications of classical and quantum statistical mechanics. Topics to be covered include the statistical basis of thermodynamics; ideal classical and quantum gases (Bose and Fermi); lattice vibrations and phonons; weak interaction expansions; phase transitions; and fluctuations and dynamics.

Instructor: Motrunich

Ph 129 abc

Mathematical Methods of Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 106 abc and ACM 95/100 abc or Ma 108 abc, or equivalents.

Mathematical methods and their application in physics. First term includes analytic and numerical methods for solving differential equations, integral equations, and transforms, and other applications of real analysis. Second term focuses on probability and statistics in physics. Third term covers group theoretic methods in physics. The three terms can be taken independently.

Instructors: Porter, Refael, Schwarz

Ph 134

String Theory

9 units (3-0-6) | third term

Prerequisites: Ph 125 ab, Ph 106 ab.

A basic course in string theory designed to be accessible to a broad audience. The main topics include the motion of relativistic point particles and strings, actions, world-sheet symmetries and currents, light-cone quantization, and the spectra of relativistic open and closed strings. The course will conclude with an exploration of D-branes, T-duality, or string thermodynamics, depending on student interest.

Ph 135 abc

Applications of Quantum Mechanics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 125 abc or equivalent.

Applications of quantum mechanics to topics in contemporary physics. Particle physics, condensed-matter physics, and quantum phenomena in the early universe will be offered first, second, third terms, respectively. Terms may be taken independently.

Instructors: Weinstein, Fisher, Kamionkowski

Ph 136 abc

Applications of Classical Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 106 abc or equivalent.

Applications of classical physics to topics of interest in contemporary "macroscopic'' physics. Continuum physics and classical field theory; elasticity and hydrodynamics; plasma physics; magnetohydrodynamics; thermodynamics and statistical mechanics; gravitation theory, including general relativity and cosmology; modern optics. Content will vary from year to year, depending on the instructor. An attempt will be made to organize the material so that the terms may be taken independently.

Ph 171

Reading and Independent Study

Units in accordance with work accomplished

Occasionally, advanced work involving reading, special problems, or independent study is carried out under the supervision of an instructor. Approval of the instructor and of the student's departmental adviser must be obtained before registering. Graded pass/fail.

Ph 172

Research in Experimental Physics

Units in accordance with work accomplished

Approval of the student's research supervisor and department adviser must be obtained before registering. Graded pass/fail.

Ph 173

Research in Theoretical Physics

Units in accordance with work accomplished

Approval of the student's research supervisor and departmental adviser must be obtained before registering. Graded pass/fail.

BE/APh/Ph 181

Biological Interfaces, Transduction, and Sensing

9 units (3-0-6) | third term

Prerequisites: APh 105, Ph129 or equivalent (students without a background in statistical physics are still encouraged to take the course-additional tutorial sessions will be arranged as needed).

Basic physics and chemical physics of interfaces between the fundamental realm of biology-molecules and cells-and the physical world. The course centers on processes that are essential for transduction to energy domains in which modern sensors operate. Information transfer from the biological realm to optical, electronic, and mechanical domains will be considered. Particular attention will be paid to both the sensitivity and the kinetics of transduction processes, and to how fluctuations affect and ultimately impose fundamental limits on such interactions.

Instructor: Roukes

CNS/Bi/Ph/CS 187

Neural Computation

9 units (3-0-6) | first term

Prerequisites: familiarity with digital circuits, probability theory, linear algebra, and differential equations. Programming will be required.

This course investigates computation by neurons. Of primary concern are models of neural computation and their neurological substrate, as well as the physics of collective computation. Thus, neurobiology is used as a motivating factor to introduce the relevant algorithms. Topics include rate-code neural networks, their differential equations, and equivalent circuits; stochastic models and their energy functions; associative memory; supervised and unsupervised learning; development; spike-based computing; single-cell computation; error and noise tolerance.

Instructor: Perona

Ph 199

Frontiers of Fundamental Physics

9 units (3-0-6) | third term

Prerequisites: Ph 125 abc, Ph 106 abc, or equivalent.

This course will explore the frontiers of research in particle physics and cosmology, focusing on physics at the Large Hadron Collider. Topics include the experimental search for the Higgs boson, supersymmetry and extra dimensions, and the study of the relevant Standard Model backgrounds. The course is geared toward seniors and first-year graduate students who are not in particle physics, although students in particle physics are welcome to attend.

Instructor: Spiropulu

Ph 205 abc

Relativistic Quantum Mechanics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 125.

Topics: the Dirac equation, second quantization, quantum electrodynamics, scattering theory, Feynman diagrams, non-Abelian gauge theories, Higgs symmetry-breaking, the Weinberg-Salam model, and renormalization.

Instructors: Schwarz, Gukov

Ph 210

Theoretical Quantum Chromodynamics

9 units (3-0-6) | third term

Prerequisites: Ph 205 ab.

Applications of quantum field theory to quantum chromodynamics, including operator product expansion, twist expansion and applications to deep inelastic scattering and Drell-Yan; effective field theories, including chiral perturbation theory, heavy quark effective theory, and soft collinear effective theory; large Nc; introduction to lattice chromodynamics. Applications to strong interaction phenomenology and weak decays.

Ph 217 abc

Introduction to the Standard Model

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 205 abc and Ph 236 abc, or equivalent.

This course deals with elementary particle physics and cosmology. Students should have at least some background in quantum field theory and general relativity. The standard model of weak and strong interactions is developed, along with predictions for Higgs physics and flavor physics. Some conjectures for physics beyond the standard model are introduced: for example, low-energy supersymmetry and warped extra dimensions. In the second half of the course, the standard picture for cosmology is discussed. The predictions of inflation for the primordial density perturbations are reviewed. The microwave background anisotropy is discussed.

Ph/CS 219 abc

Quantum Computation

9 units (3-0-6) | first, second terms

Prerequisites: Ph 129 abc or equivalent.

The theory of quantum information and quantum computation. Overview of classical information theory, compression of quantum information, transmission of quantum information through noisy channels, quantum error-correcting codes, quantum cryptography and teleportation. Overview of classical complexity theory, quantum complexity, efficient quantum algorithms, fault-tolerant quantum computation, physical implementations of quantum computation.

Instructors: Kitaev, Preskill

Ph/APh 223 abc

Advanced Condensed-Matter Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 125 or equivalent, or instructor's permission.

Advanced topics in condensed-matter physics, emphasizing the application of formal quantum field theory and group theory methods to many-body systems. Selected topics may include path integral and canonical formalisms, Green's function techniques and Feynman diagrams, Fermi liquid theory, Luttinger liquid theory, symmetry breaking and Landau-Ginzburg theory of phase transitions, group theory and its applications, field theory for interacting bosons and superfluidity, superconductivity, Kondo effect, Hubbard and t-J models, gauge theory, fractional quantum Hall effect, anyons, and topological field theory.

Ph 229 abc

Advanced Mathematical Methods of Physics

9 units (3-0-6) | first, second terms

Prerequisites: Ph 129 abc or equivalent.

Advanced topics in geometry and topology that are widely used in modern theoretical physics. Emphasis will be on understanding and applications more than on rigor and proofs. First term will cover basic concepts in topology and manifold theory. Second term will include Riemannian geometry, fiber bundles, characteristic classes, and index theorems. Third term will include anomalies in gauge-field theories and the theory of Riemann surfaces, with emphasis on applications to string theory.

Instructor: Ooguri

Ph 230 abc

Elementary Particle Theory

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 205 abc or equivalent.

Advanced methods in quantum field theory. First term: introduction to supersymmetry, including the minimal supersymmetric extension of the standard model, supersymmetric grand unified theories, extended supersymmetry, supergravity, and supersymmetric theories in higher dimensions. Second and third terms: nonperturbative phenomena in non-Abelian gauge field theories, including quark confinement, chiral symmetry breaking, anomalies, instantons, the 1/N expansion, lattice gauge theories, and topological solitons.

Ph 231 abc

Elementary Particle Physics

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 125 or equivalent.

An introduction to ele-mentary particle physics, stressing experimental phenomena and their theoretical interpretations. The standard model and its confrontation with experiment will be covered. Current notions for particle physics beyond the standard model will be explored, along with possible experimental signatures. Experimental techniques will also be discussed, including an introduction to accelerator physics.

Ph 232

Introduction to Topological Field Theory

9 units (3-0-6) | second term

Prerequisites: Ph 205.

Topological field theories are the simplest examples of quantum field theories which, in a sense, are exactly solvable and generally covariant. During the past twenty years they have been the main source of interaction between physics and mathematics. Thus, ideas from gauge theory led to the discovery of new topological invariants for 3-manifolds and 4-manifolds. By now, topological quantum field theory (TQFT) has evolved into a vast subject, and the main goal of this course is to give an accessible introduction to this elegant subject.

Instructor: Kitaev

Ph 235 abc

Introduction to Supersymmetry and String Theory

9 units (3-0-6) | second, third terms

Prerequisites: Ph 205.

First term: introduction to supersymmetry. After explaining the basic concepts of supersymmetry, the emphasis will be on formulating and analyzing the minimal supersymmetric extension of the standard model and supersymmetric grand unified theories. There will also be brief introductions to supersymmetric theories in higher dimensions, theories with extended supersymmetry, and supergravity. Second term: introduction to superstring theory. Topics to be discussed include relativistic strings and their quantization, perturbative string theory, low energy effective supergravity theories, p-brane solutions and p-brane world volume theories, compactification of extra dimensions, M theory and F theory, dualities relating various superstring and M theory configurations, problems and prospects.

Instructor: Kapustin

Ph 236 abc

Relativity

9 units (3-0-6) | first, second, third terms

Prerequisites: a mastery of special relativity at the level of Goldstein's , or of Jackson's.

Classical MechanicsClassical Electrodynamics A systematic exposition of Einstein's general theory of relativity and its applications to gravitational waves, black holes, relativistic stars, causal structure of space-time, cosmology and brane worlds.

Instructor: Chen

Ph 237

Gravitational Waves

9 units (3-0-6) | third term

Prerequisites: Ph 236 a.

The theory and astrophysical phenomenology of gravitational-wave sources (black holes, neutron stars, compact binaries, early-universe phenomena, etc.). Gravitational-wave detectors (LIGO, LISA, and others), and data analysis.

Ph 242 ab

Physics Seminar

3 units (2-0-1) | first, second terms

Topics in physics emphasizing current research at Caltech. One two-hour meeting per week. Speakers will be chosen from both faculty and students. Registration restricted to first-year graduate students in physics; exceptions only with permission of instructor. Graded pass/fail.

Instructor: Stone

Ph 250 abc

Introduction to String Theory

9 units (3-0-6) | first, second, third terms

Prerequisites: Ph 205 or equivalent.

The first two terms will focus largely on the bosonic string. Topics covered will include conformal invariance and construction of string scattering amplitudes, the origins of gauge interactions and gravity from string theory, T-duality, and D-branes. The third term will cover perturbative aspects of superstrings, supergravity, various BPS branes, and string dualities.

Ph 300

Thesis Research

Units in accordance with work accomplished

Ph 300 is elected in place of Ph 172 or Ph 173 when the student has progressed to the point where research leads directly toward the thesis for the degree of Doctor of Philosophy. Approval of the student's research supervisor and department adviser or registration representative must be obtained before registering. Graded pass/fail.

Published Date: July 28, 2022