This Course and Program Catalogue is effective from May 2014 to April 2015.

Not all courses described in the Course and Program Catalogue are offered each year. For a list of course offerings in 2014-2015, please consult the class search website.

For general registration information, please visit students.usask.ca.

As of 2005-2006, certain course abbreviations have changed. Students with credit for a course under its former label may not take the relabeled course for credit.

The following conventions are used for course numbering:

- 010-099 represent non-degree level courses
- 100-699 represent undergraduate degree level courses
- 700-999 represent graduate degree level courses

Course Term and Instructional Code Designations are outlined here.

Please use the following form to look up courses and find detailed information on course prerequisites, corequisites, and other special notes. To view all 100-level courses in a subject, select a Subject Code and type 1% in the Course Number field. (200-level = 2%, etc.)

Physics and the Universe

Provides the first part of an introduction to physics. Topics include force, energy, momentum and collisions, torque and angular momentum, electric and magnetic fields, electric currents and circuits. Some applications of physics in technology and the health sciences are also discussed.

Physics for the Life Sciences

Introduces students to aspects of physics which are of particular relevance for the health and life sciences. This course can be used as the second part of an introduction to physics. Topics include fluid mechanics, oscillations and waves, thermal physics, optics, quantum physics, and nuclear physics. Emphasis is placed on bio-medical applications of physics.

Physics and Technology

Introduces students to aspects of physics with an emphasis on applications in technology and the physical sciences. This course can be used as the second part of an introduction to physics for students in the physical sciences or as a science elective for engineering students. Topics include fluid mechanics, oscillations and waves, temperature and ideal gas law, optics, special relativity, quantum physics, and nuclear physics.

Introduction to Quantum and Relativistic Phenomena

An introduction to relativistic and quantum systems, including the physics of atoms, molecules, solids, nuclei, and elementary particles.

Introduction to Electricity and Magnetism

Begins with an introduction to electricity: elementary electric charge, Coulomb's law, concepts of electric field and electrostatic potential, work, energy and capacitance, and dielectrics. The second part of the class is devoted to circuit analysis: voltage, current, resistance, power, Ohm's law, DC series/parallel circuits, Kirchhoff's laws, circuits with capacitors and R-C transients. The third part of the class focuses on concepts of electromagnetism: magnetic field and magnetic flux, forces acting on a charge and current carrying conductor, and analysis of series magnetic circuits.

Mechanics I

An introduction to classical mechanics of single-particle systems using Newtonian, Lagrangian, and Hamiltonian methods. Applications include linear and non-linear oscillations and gravitation.

Electricity and Magnetism Laboratory

This laboratory course explores basic elements of electric circuits and electronics through experiments. Students will also learn how to measure magnetic fields through inductance and Hall probes. There will be five experiments and students will need 1.5 hours per experiment. For each experiment there will also be a 1 hour lecture.

Optics Laboratory

A laboratory course that explores geometric optics and wave optics through experiments. Topics include image formation with mirrors and lenses, diffraction and interference patterns, and polarization. There will be five experiments and students will need 1.5 hours per experiment. For each experiment there will also be a 1 hour lecture.

Foundations of Modern Physics

Introduces Special Relativity and the foundations of Quantum Mechanics. Topics in relativity include Lorentz transformations, time dilation, length contraction, space-time diagrams, relativistic addition of velocities, and the relativistic definitions of energy and momentum. Topics in Quantum Mechanics include quantization of energy levels, wave-particle duality, and the tunnel effect.

Concepts of Radiation Physics

Introduces the essential radiation physics concepts of relevance for nuclear energy, radiation therapy, radiation protection and medical imaging professionals.Topics include basic constituents of matter; mass-energy equivalence; atomic mass unit; relativistic mass; de Broglie wavelength; Compton wavelength; excited states and radiation; nuclear stability and radioactive decay; radioactive disintegration laws; activation analysis; energetics of nuclear decays and reactions; binding energy and separation energies; nuclear fission and nuclear fusion; interaction of radiation with matter; charged particle interactions: range and stopping power; photon attenuation: photoelectric effect, Compton scattering and pair production; neutron interactions: elastic and inelastic scattering, capture, nuclear fission; neutron attenuation. Further topics include the physics of nuclear reactors; chain reactions; criticality of a reactor; elements of radiation protection: radiation units, quality factor and equivalent dose.

Special Topics

Offered occasionally by visiting faculty and in other special situations. Students interested in these courses should contact the department for more information.

Special Topics

Offered occasionally by visiting faculty and in other special situations. Students interested in these courses should contact the department for more information.

Mechanics II

Continues the study of the classical mechanics of single-particle, multi-particle, and continuous systems in Newtonian, Lagrangian, and Hamiltonian methods. Applications include motion in a central force, non-inertial reference frames, rigid bodies, coupled oscillations, and fluids.

Intermediate Electromagnetism

Vector analysis, electrostatics, electric fields in matter, magnetostatics and magnetic fields in matter. Electrodynamics: Faraday's law of induction. Displacement current and the Ampere-Maxwell equation. Maxwell's equations in differential and integral form. Special theory of relativity: magnetism as a relativistic phenomenon.

Statistical and Thermal Physics

Following a brief introduction to basic probability concepts the course applies statistical ideas to systems of particles in equilibrium so as to develop the basic notions of statistical mechanics. Macroscopic and microscopic aspects are discussed and illustrated in detail. Topics covered include partition functions, specific heats of molecules, effusion, quantum statistics of ideal gases, systems of interacting particles and chemical equilibrium.

Quantum Mechanics I

The Schrödinger equation and its implications are discussed for several important quantum systems, including the quantum harmonic oscillator and one-electron atoms. Further topics include barrier-penetration, angular momentum in quantum mechanics, spin, and time-independent perturbation theory. The tutorial will develop problem solving skills and techniques using modern tools.

CaNoRock Canada Norway Student Sounding Rocket Course

A field course held at the Andøya Rocket Range in Andenes, Norway. Students will assemble scientific instruments, test these instruments, collect the data remotely from the rocket's telemetry systems during the rocket's flight, and analyse and present the interpreted data.

Special Topics

Offered occasionally by visiting faculty and in other special situations to cover, in depth, topics that are not thoroughly covered in regularly offered courses.

Special Topics

Offered occasionally by visiting faculty and in other special situations to cover, in depth, topics that are not thoroughly covered in regularly offered courses.

Techniques of Theoretical Physics I

Designed to develop those mathematical skills which are required for solving physical problems. Emphasis is placed on the various initial value and boundary value problems occurring in physics and engineering. This course requires that students do a large number of homework problems.

Techniques of Experimental Physics

Intended to make the student familiar with a variety of modern techniques in Experimental Physics including physical properties of materials and their use in the laboratory, radiation sources and radiation detection, vacuum techniques and cryogenics.

Introduction to Nuclear and Particle Physics

An introduction to the physics of the nucleus and of the fundamental particles and their interactions. Topics in nuclear physics include nuclear phenomenology, radioactive decay, nuclear reactions; nuclear models: semi-empirical mass formula, shell model, collective models, the deuteron and the nucleon-nucleon interaction. Topics in particle physics include strong and electroweak interactions; global and local symmetries of the weak and strong interactions; the neutral Kaons and CP violation; Feynman diagrams; the Standard Model: quarks, gluons and colour; decay and reaction probabilities; hadron production; meson and baryon masses; charmonium; asymptotic freedom; neutrino oscillations.

Modern Physics Laboratory IV

This laboratory course focuses on advanced nuclear techniques, including coincidence measurements and neutron activation analysis. There will be five experiments and students will need 3 hours per experiment. For each experiment there will also be a 2 hour lecture.

Electricity and Magnetism II

This course provides an advanced treatment of electromagnetic waves in matter, electromagnetic radiation, and relativistic electrodynamics.

Physics of Plasmas and Fluids

Provides students with an exposure to basic ideas of fluid and plasma dynamics as used in various applications, including ocean and atmosphere motions, space and laboratory plasmas, and controlled thermonuclear fusion. A unified discussion of neutral fluids and plasmas is emphasized whenever possible. Topics include fluid (moment) models, motion of charged particles in electric and magnetic fields, oscillations and waves in neutral fluids and plasmas, plasma properties and equilibria.

Solid State Physics

Covers perturbation theory, crystal structure and binding of solids, lattice vibrations, electrons in crystaline lattices, magnetic and transport properties of solids, and superconductivity.

Synchrotron Physics

Provides an introduction to the physics of synchrotrons and their applications. The first part introduces accelerator physics, synchrotron radiation and its sources, and beamline optics. The second part discusses X-ray spectroscopy with synchrotrons as well as elastic and inelastic scattering.

Quantum Mechanics II

Linear vector spaces and quantum mechanics; hermitian and unitary linear operators; Schrodinger equation in various representations; the operator method as applied to the harmonic oscillator and to angular momentum eigenvalues; the spin statistics theorem; minimal coupling of electromagnetic fields; time independent perturbation theory and applications.

Quantum Mechanics III

Continues PHYS 481 and begins with an extensive discussion of time dependence in quantum mechanics. Exactly solvable problems such as spin-magnetic resonance are used to illustrate the time-dependent perturbation series. Applications include emission and absorption of radiation, multipole selection rules, and electron scattering from atoms and nuclei; Further topics discussed in detail are symmetry in quantum mechanics, rotation matrices and applications, many particle systems, collision theory, and variational methods including Hartree-Fock theory.

Physics Seminars

Students are required to attend both Departmental seminars and special student seminars. In each case the seminar material is intended to introduce students to some of the new developments in Physics and Engineering Physics.

Physics Research Project

The student will work on an advanced research project in Physics under the supervision of a faculty member in the department specializing in the selected area. The project will be evaluated by a committee (including the supervisor) on the basis of oral and written reports.

Extended Research Project in Physics

The student will work on a research project in physics under the supervision of a faculty member. The project will be evaluated by a committee (including the supervisor) on the basis of two oral and two written reports.

Research Term in Physics

Course allows students to get credit for spending a term as a member of a research group, or for participation in international exchange programs with a strong research component. The student is expected to engage full time in a physics research project at a research facility or a university under the supervision of a faculty member or a research scientist from the host institution. The time frame for participation in the research project should be 12-16 weeks, including special skills training where required. The student's contribution to the research project must be significant enough to justify co-authorship in a journal or conference paper on the research project. The student will be asked to provide a written outline of scientific foundations and motivations for the research six weeks after the start of the project.

Special Topics

Offered occasionally by visiting faculty and in other special situations to cover, in depth, topics that are not thoroughly covered in regularly offered courses.

Special Topics

Offered occasionally by visiting faculty and in other special situations to cover, in depth, topics that are not thoroughly covered in regularly offered courses.

Classical Mechanics

Lagrange's equation of Motion, Hamilton formulation, Phase-space considerations, Liouville theorem, Poisson brackets, Action-angle variables, Hamilton-Jacobi Equation, Integrable systems, Canonical Perturbation theory, KAM theorem, Phase-space mapping, Henon, Standard and tangent Maps, Local and Global Chaos, Dissipative systems.

Electromagnetic Theory

Topics include boundary-value problems of electrostatics and magnetostatics, time varying fields, radiation and multipole fields.

Electrodynamics

This course provides advanced treatment of electromagnetic waves in matter, radiation and relativistic electrodynamics.

Introduction to Aeronomy

The structure and composition of the Earth's atmosphere; mean circulation, tides and wave motions; the major photochemical processes and their implications; the physical processes of the ionosphere and the magnetosphere; and experimental methods.

Radio Physics of Upper Atmosphere

Deals with the application of radio methods to studies of the upper atmosphere. Topics discussed include the magneto-ionic theory; scattering of radio waves by meteors and aurora, scattering, generation and absorption of radio waves in the solar and terrestrial atmospheres, solar-terrestrial-relations and the methods of radio astronomy applied to upper atmospheric measurements.

Ionospheric and Magnetospheric Physics

The Earth's ionosphere and magnetosphere, also for other planets. Techniques of investigation, physical processes, structure and models.

Atmospheric Spectroscopy and Radiative Transfer

Solar and terrestrial radiation; absorption, emission and scattering in terrestrial and planetary atmospheres; radiative transfer; remote sensing of atmospheric properties; climate models (greenhouse effect, atmospheric evolution).

Methods of Experimental Synchrotron Science

This is an interdisciplinary special topic course targeted for graduate students with interest in synchrotron radiation and synchrotron science. The following topics are normally covered: spectroscopy with microfocussed beams of soft x-rays and infrared; x-ray diffraction studies of the electron and molecular structure of crystallizable proteins; near edge absorption spectroscopy; fine structure of extended x-ray absorption spectra.

General Relativity and Gravitation

Development of the physical ideas and mathematical skills leading to general relativity as a theory of gravitation; solutions of the Einstein field equations and observational tests of general relativity; applications to black holes and cosmological models.

Introductory Nuclear Physics

Introduction to electromagnetic and weak interactions as relevant to nuclear and particle physics. Symmetries in sub-atomic physics, weak decays, selection rules and electromagnetic processes.

Radiological Physics

Use of radioisotopes in medical imaging, devices and instrumentation for nuclear medicine imaging, principles of nuclear tomography, radiation protection, risk vs. benefit, facility design for radiation protection, radiobiology.

Plasma Physics

Discusses the basic concepts of plasma physics. Reading of assigned literature in plasma physics is required.

Plasma Waves I

Dispersion relations are derived for small amplitude waves in plasmas, both in the presence and in the absence of magnetic fields. The topics treated in this course include the kinetic model of the plasma, Landau damping, instabilities, the effect of inhomogeneities or wave propagation, and the effect of oscillating external fields on waves and instabilities.

Plasma Waves II

Deals with nonlinear wave phenomena in plasma physics. Quasilinear theory, the theory of a single plasma mode and the equation of Korteweg-de Vries are covered. Other topics to be chosen from the Dupree-Weinstock theory of plasma turbulence, fluctuations, wave scattering and applications to fusion plasmas.

Plasma Transport Properties and Diagnostic Techniques

Provides a kinetic theory treatment of plasma transport phenomena - conductivity, diffusion, heat flow - and the relaxation times for particle deflection, momentum transfer, energy relaxation. Various plasma measurement techniques are then discussed, including the use of microwaves, probes, laser scattering and particle energy analyzers.

Condensed Matter Physics I

A graduate level introductory course in condensed matter physics, focusing on the properties of crystalline solids. The course will cover crystal structure and symmetries, electronic properties and bandstructure, semiconductors, binding of solids and lattice vibrations, and optical properties of solids. Modern computational and experimental methods will be introduced as appropriate.

Statistical Mechanics

As part of basic training of graduate students, this core course aims to reinforce the student's understanding of the fundamental concepts and techniques of statistical mechanics, and to advance the student's general knowledge of phase transitions and critical phenomena. The course will not only broaden the student's general knowledge of statistical physics, but will also expose the student to a variety of current research topics. In this course, three basic ensembles (microcanonical, canonical, grandcanonical) are first reviewed for both classical and quantum-mechanical statistical mechanics, and the classical limit of ideal gas is discussed. The quantum-mechanical collective phenomena in Fermi and Bose systems are examined. Finally, the techniques for analysing quantum critical phenomena and the Landau theory of phase transition are studied in detail, along with their applications to various physical systems.

Quantum Mechanics

Concepts in advanced quantum mechanics. Topics include perturbation theory, relativistic corrections, scattering theory, second quantization, non-relativistic QED, and selected applications to subatomic, atomic, molecular, or solid-state systems.

Quantum Field Theory

Fundamental concepts in quantum field theory. Topics include relativistic field equations; canonical and path integral quantization; symmetries, conservation laws, and symmetry breaking; interacting field theories relevant to condensed matter and subatomic physics; tree-level processes.

Relativistic Quantum Mechanics

The course continues the study of topics in advanced quantum mechanics with a focus on relativistic quantum mechanics: Quantization of electromagnetic fields, photon emission and absorption, scattering of photons, Klein-Gordon equation, Dirac equation, non-relativistic limit of the Klein-Gordon and Dirac equations, relativistic corrections to the Schrodinger equation, quantization of the Klein-Gordon and Dirac fields, and scattering cross sections in quantum electrodynamics.

Selected Topics in Condensed Matter Physics

Advanced topics are selected to aid graduate students with their research. Depending on student interests the following subjects may be covered: electronic structure of advanced materials, high temperature superconductors, and biomaterials. Experimental methods in solid state physics and material science. Nanoscale physics, surface phenomena and soft condensed matter physics.

Selected Topics in Physics and Engineering Physics

Advanced topics in Physics and Engineering Physics selected to aid graduate students with their research. Consists of assigned readings in texts and/or scientific journals, related discussions, and additional lectures.

Selected Topics in Theoretical Physics

Advanced topics in theoretical physics selected to aid graduate students with their research. Consists of assigned readings in texts and/or scientific journals, related discussions, and additional lectures.

Selected Topics in Subatomic Physics

Advanced topics in subatomic physics selected to aid graduate students with their research. Consists of assigned readings in texts and/or scientific journals, related discussions, and additional lectures.

Selected Topics in Plasma Physics

Advanced topics in plasma physics selected to aid graduate students with their research. Consists of assigned readings in texts and/or scientific journals, related discussions, and additional lectures.

Selected Topics in Space and Atmospheric Physics

Advanced topics in space and atmospheric physics selected to aid graduate students with their research. Consists of assigned readings in texts and/or scientific journals, related discussions, and additional lectures.

Special Topics

Consists of assigned reading in texts and scientific journals on which the students report; additional lectures by the professor in charge are also given. Depending on the interests of the students, the topics are in the field of nuclear, or theoretical or upper atmospheric physics.

Special Topics

Offered occasionally in special situations. Students interested in these courses should contact the department for more information.

Seminar

Papers on recent developments in Physics and Engineering Physics are given. Candidates for the Master's degree and for the Ph.D. degree in this department are required to participate.

Research

Students writing a Master's thesis in physics must register for this course.

Research

Students writing a Ph.D. thesis in physics must register for this course.

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