Department of Physics
3302 Herzberg Bldg.
613-520-4320
http://physics.carleton.ca
This section presents the requirements for programs in:
Program Requirements
M.Sc. Physics (5.0 credits)
1. 2.0 credits in: | 2.0 | |
PHYS 5601 [0.5] | Experimental Techniques of Nuclear and Elementary Particle Physics | |
PHYS 5602 [0.5] | Physics of Elementary Particles | |
PHYS 5701 [0.5] | Intermediate Quantum Mechanics with Applications | |
PHYS 5702 [0.5] | Relativistic Quantum Mechanics | |
2. 0.5 credit in: | 0.5 | |
PHYS 5002 [0.5] | Computational Physics (equivalent course in computing physics) | |
3. 2.5 credits in: | 2.5 | |
PHYS 5909 [2.5] | M.Sc. Thesis (defended at an oral examination) | |
4. Participation in the seminar series of the Ottawa-Carleton Institute of Physics | ||
Total Credits | 5.0 |
Notes:
- Students with academic preparation particularly well suited for their chosen field of study may have their course credit requirements reduced to 2.0 credits. In this case, a 3.0 credit thesis will be required.
- Of the 2.5 credits of course work, no more than 1.5 credits may be fulfilled by Selected Topics such as PHYS 5900 [1.0], PHYS 5901. In special cases, the requirements may also be met by taking 5.0 credits of course work. 1.0 credit must be the Selected Topics course PHYS 5900
Requirements - Medical Physics stream: | ||
1. 0.5 credit in: | 0.5 | |
PHYS 5203 [0.5] | Medical Radiation Physics | |
2. 0.5 credit in: | 0.5 | |
PHYS 5002 [0.5] | Computational Physics | |
3. 0.5 credit from: | 0.5 | |
PHYS 5204 [0.5] | Physics of Medical Imaging (for imaging) | |
PHYS 5206 [0.5] | Medical Radiotherapy Physics (for therapy) | |
PHYS 5207 [0.5] | Radiobiology (for biophysics. Alternately, course in Cell Biology, Physiology, Anatomy may be chosen) | |
4. 0.5 credit in PHYS from an area of physics other than medical physics | 0.5 | |
5. 0.5 additional credit in PHYS | 0.5 | |
6. 2.5 credits in: | 2.5 | |
PHYS 5909 [2.5] | M.Sc. Thesis (defended at an oral examination) | |
7. Participation in the seminar series of the Ottawa-Carleton Institute for Physics | ||
Total Credits | 5.0 |
Notes:
- Students with academic preparation particularly well suited for their chosen field of study may have their course credit requirements reduced to 2.0 credits. In this case, a 3.0 credit thesis will be required.
- Students with a medical/health physics background may have the selection of required courses adjusted to reflect their preparation and may receive advanced standing for equivalent courses.
- A selection from PHYS 5208, PHYS 5209, or, (with approval) other appropriate courses in physics, engineering, computer science, business or law can be used to complete the program.
- Of the 2.5 credits of course work, no more than 1.5 credits may be fulfilled by Selected Topics such as PHYS 5900 PHYS 5900PHYS 5900PHYS 5900, PHYS 5901. In special cases, the requirements may also be met by taking 5.0 credits of course work. 1.0 credit must be the Selected Topics course PHYS 5900 [1.0].
Requirements - Physics in Modern Technology Stream: | ||
1. 1.0 credit from: | 1.0 | |
PHYS 5002 [0.5] | Computational Physics | |
PHYJ 5003 [0.5] | Computer Simulations in Physics | |
PHYJ 5004 [0.5] | Computational Physics I | |
PHYJ 5005 [0.5] | Computational Physics II | |
2. 2.0 additional credits in PHYS | 2.0 | |
3. 1.0 credit in: | 1.0 | |
PHYS 5905 [1.0] | Physics in Modern Technology Work Term | |
Total Credits | 4.0 |
Note:
Students enrolled in the physics in modern technology stream are required to complete a work term rather than a research thesis. Students in this stream who wish to pursue a research degree should consult with the graduate supervisor. Although every effort is made to find a work term position for every student enrolled in the physics in modern technology stream, no guarantee of employment can be made. To minimize the likelihood of a work term position not being found, enrollment will be limited to reflect the availability of work term placements. In the event that a work term placement cannot be found, students may fulfill the M.Sc. requirements with 4.0 credits of course work.
Guidelines for Completion of Master's Degree
With the exception of those students in the physics in modern technology stream, full-time master's candidates are expected to complete all requirements in six terms of registered full-time study. Part-time master's candidates are expected to complete their degree requirements within an elapsed period of three to four calendar years after the date of initial registration.
Students in the physics in modern technology stream are normally expected to complete all their requirements in three successive terms of registered full-time study.
Ph.D. Physics (10.0 credits)
Requirements: | ||
1. 2.0 credits course work at the graduate level | 2.0 | |
2. Comprehensive examination designed to demonstrate overall ability in physics and in the candidate's research area, normally within the first year of study. This takes the form of a written examination followed, if necessary, by an oral examination | ||
3. Participation in the seminar series of the Ottawa-Carleton Institute for Physics | ||
4. 8.0 credits in: | 8.0 | |
PHYS 6909 [8.0] | Ph.D. Thesis (which will be defended at an oral examination. The examining board for all theses will include members of the Ottawa-Carleton Institute for Physics from both Departments of Physics. The external examiner of the thesis will be external to both Departments of Physics.) | |
Total Credits | 10.0 |
Notes
- Students in experimental or theoretical particle physics who lack any of the relevant courses recommended for the M.Sc. program must complete them (or the equivalents) by the end of their Ph.D. program. In addition they should complete PHYS 6601 and PHYS 6602
- Students in medical physics must have completed, either within this degree (as part of the minimum 2.0 course credits) or in prior graduate studies:
PHYS 5203 [0.5] Medical Radiation Physics (or equivalent) PHYS 5204 [0.5] Physics of Medical Imaging (or equivalent) PHYS 5206 [0.5] Medical Radiotherapy Physics (or equivalent) PHYS 5207 [0.5] Radiobiology (or equivalent) PHYS 5209 [0.5] Medical Physics Practical Measurements (or equivalent) PHYS 5210 [0.0] Anatomy and Physiology for Medical Physicists (or equivalent) - 0.5 credit appropriate physics course from an area of physics outside medical physics - In addition it is also strongly recommended to have completed 0.5 credit in a computational physics course, such as PHYS 5002, within the minimum 2.0 credits of this degree or in prior graduate studies. - Irrespective of courses taken previously at another institution, students may be required to complete one or more of PHYS 5204, PHYS 5206, or PHYS 5207 as preparation for their thesis research.
Guidelines for Completion of Doctoral Degree
Full-time Ph.D. candidates admitted on the basis of an M.Sc. are expected to complete all requirements within an elapsed period of four to five years after the date of initial registration. Part-time Ph.D. candidates are expected to complete all requirements within an elapsed period of six years after the date of initial registration.
Residence Requirements
For the Ph.D. degree (from B.Sc.): at least three years of full-time study (or equivalent).
For the Ph.D. degree (from M.Sc.): at least two years of full-time study (or equivalent).
Physics (PHYS) Courses
With the exception of PHYS 5701 Intermediate Quantum Mechanics with Applications and PHYS 5302 Classical Electrodynamics, which may be offered at either Carleton or the University of Ottawa, all PHYS courses are offered only at Carleton, and all PHYJ courses are offered only at the University of Ottawa.
Computational Physics
Computational methods used in analysis of experimental data. Introduction to probability and random variables. Monte Carlo methods for simulation of random processes. Statistical methods for parameter estimation and hypothesis tests. Confidence intervals. Multivariate data classification. Unfolding methods. Examples taken primarily from particle and medical physics.
Also offered at the undergraduate level, with different requirements, as PHYS 4807, for which additional credit is precluded.
Classical Mechanics and Theory of Fields
Hamilton's principle; conservation laws; canonical transformations; Hamilton-Jacobi theory; Lagrangian formulation of classical field theory.
Introduction to Medical Imaging Principles and Technology
Basic principles and technological implementation of x-ray, nuclear medicine, magnetic resonance imaging (MRI), and other imaging modalities used in medicine. Contrast, resolution, storage requirements for digital images. Applications outside of medicine, future trends.
Special Topics in Molecular Spectroscopy
Topics may include: electronic spectra of diatomic and triatomic molecules and their interpretation using molecular orbital diagrams; Raman and resonance Raman spectroscopy; symmetry aspects of vibrational and electronic levels of ions and molecules in solids; the presence of weak and strong resonant laser radiation.
Prerequisite(s): permission of the Department.
Medical Radiation Physics
Interaction of electromagnetic radiation with matter. Sources: X-ray, accelerators, radionuclide. Charged particle interaction mechanisms, stopping powers, kerma, dose. Introduction to dosimetry. Units, measurements, dosimetry devices.
Physics of Medical Imaging
Physical foundation of and recent developments in transmission X-ray imaging, computerized tomography, nuclear medicine, magnetic resonance imaging, and ultrasound, for the specialist imaging physicist. Image quality, contrast, resolution, SNR, MTF, DQE. Introduction to image processing, system performance assessment.
Medical Radiotherapy Physics
Radiation therapy process and physics. Ion chamber dosimetry, Monte Carlo techniques of radiation transport, cavity theories, external beam therapy, brachytherapy, dosimetry protocols, detectors used in radiation therapy. Treatment planning, monitor unit calculations, intensity-modulated radiation therapy. Novel and alternate techniques.
Radiobiology
Physics and chemistry of radiation interactions. Cell biology, DNA damage and repair, survival curves and models, radiosensitivity, oxygen effect. Linear energy transfer, relative biological effectiveness. Whole body radiation effects, radioprotectors, radiosensitizers. Hyperthermia. Molecular techniques in radiobiology. Model tumour systems.
Radiation Protection
Dose quantities, effects of radiation exposure, fetal risks, scientific basis for protection, dose limits. Background radiation, dose from internal radionuclides. Doses in radiology, incidents in radiation therapy. Shielding design, working with radioactive materials. Instruments and measurement. Radiation protection organizations.
Medical Physics Practical Measurements
Experience with current clinical medical imaging and cancer therapy equipment, and dosimetry and biophysics instrumentation. The course requires completion of experimental projects on medical imaging, radiotherapy, dosimetry, and biophysics, conducted at local clinics and NRC laboratories.
Anatomy and Physiology for Medical Physicists
An overview of human anatomy and physiology as background for the application of physics to cancer therapy and medical imaging. Anatomy as depicted by imaging technologies such as CT, mri, and radiography will be emphasized. Graded Sat/Uns.
Advanced Topics in Medical Physics
Topics may include medical imaging physics, cancer therapy physics, medical biophysics, or radiation protection and health physics.
Classical Electrodynamics
Covariant formulation of electrodynamics; Liénard-Wiechert potentials; radiation reaction; plasma physics; dispersion relations.
Physical Applications of Fourier Analysis
Fourier transform, convolution. Sampling theorem. Applications to imaging: descriptors of spatial resolution, filtering. Correlation, noise power. Discrete Fourier transform, FFT. Filtering of noisy signals. Image reconstruction in computed tomography and magnetic resonance. Laplace transform. Integral transforms, application to boundary value problems.
Modern Optics
Electromagnetic wave propagation; reflection, refraction; Gaussian beams; guided waves. Laser theory: stimulated emission, cavity optics, gain and bandwidth, atomic and molecular lasers. Mode locking, Q switching. Diffraction theory, coherence, Fourier optics, holography, laser applications. Optical communication systems, nonlinear effects: devices, fibre sensors, integrated optics.
Also offered at the undergraduate level, with different requirements, as PHYS 4208, for which additional credit is precluded.
Experimental Techniques of Nuclear and Elementary Particle Physics
The interaction of radiation and high energy particles with matter; experimental methods of detection and acceleration of particles; use of relativistic kinematics; counting statistics.
Physics of Elementary Particles
Properties of leptons, quarks, and hadrons. The fundamental interactions. Conservation laws; invariance principles and quantum numbers. Resonances observed in hadron-hadron interactions. Three body phase space. Dalitz plot. Quark model of hadrons, mass formulae. Weak interactions; parity violation, decay of neutral kaons; CP violation; Cabibbo theory.
Also offered at the undergraduate level, with different requirements, as PHYS 4602, for which additional credit is precluded.
Intermediate Nuclear Physics
Properties of the deuteron and the neutron-proton force. Nucleon-nucleon forces, isospin and charge independence. Nuclear models. Scattering theory. Interpretation of n-p and p-p scattering experiments. Interaction of nucleons with electrons. Interaction of nuclei with radiation.
Intermediate Quantum Mechanics with Applications
Angular momentum and rotation operations; Wigner and Racah coefficients; several and many electron problem in atoms; variational and Hartree-Fock formalism; introduction to second quantized field theory; scattering theory.
Relativistic Quantum Mechanics
Relativistic wave equations. Expansion of S matrix in Feynman perturbation series. Feynman rules. An introduction to quantum electro-dynamics with some second quantization. Gauge theories. May include introduction to Standard Model.
Methods of Theoretical Physics I
This course and PHYS 5802 are designed for students who wish to acquire a wide background of mathematical techniques. Topics can include complex variables, evaluation of integrals, approximation techniques, dispersion relations, Pade approximants, boundary value problems, Green's functions, integral equations.
Methods of Theoretical Physics II
This course complements PHYS 5801.Topics include group theory, discussion of SU2, SU3, and other symmetry groups. Lorentz group.
Introduction to General Relativity
Special relativity using tensor analysis. Stress energy tensors for matter and electromagnetism. Differential geometry and Einstein's field equations. Applications may include the solar system, black holes, gravitational waves, and cosmology.
Lectures three hours a week.
Selected Topics in Physics (M.Sc.)
A student may, with the permission of the Department, take more than one selected topic, in which case each full course is counted for credit.
Selected Topics in Physics (M.Sc.)
Physics in Modern Technology Work Term
Experience for students enrolled in the physics in modern technology stream. To receive course credit, students must receive satisfactory evaluations for their work term employment. Written and oral reports describing the work term project are required.
M.Sc. Thesis
Particle Physics Phenomenology
This course covers much of the required knowledge for research in particle physics from both the experimental and theoretical points of view. Topics may include: standard model, parton model, quark model, hadron spectroscopy, and tests of QCD.
Advanced Topics in Particle Physics
Phenomenology. This course will consist of a variety of seminars and short lecture courses, and will cover topics of immediate interest to the research program of the department.
Quantum Field Theory
Relativistic quantum field theory; second quantization of Bose and Fermi fields; reduction and LSZ formalism; perturbation expansion and proof of renormalizability of quantum field theories; calculations of radiative corrections and applications.
Selected Topics in Physics (Ph.D.)
Selected Topics in Physics (Ph.D.)
Ph.D. Thesis
Summer session: some of the courses listed in this Calendar are offered during the summer. Hours and scheduling for summer session courses will differ significantly from those reported in the fall/winter Calendar. To determine the scheduling and hours for summer session classes, consult the class schedule at central.carleton.ca
Not all courses listed are offered in a given year. For an up-to-date statement of course offerings for the current session and to determine the term of offering, consult the class schedule at central.carleton.ca
Admission Requirements
Accelerated Pathway
The accelerated pathway in the Department of Physics is a flexible and individualized plan of graduate study. Students in their final year of a Carleton B.Sc. Honours degree in Physics with demonstrated excellent aptitude for research may qualify for this option.
Students in their third-year of study in the B.Sc. Honours degree in Physics should consult with both the Undergraduate Advisor and the Graduate Advisor to determine if the accelerated pathway is appropriate for them and to confirm their selection of courses and Honours project supervisor for their final year of undergraduate studies.
Particle physics accelerated pathway: students must complete PHYS 5002 Computational Physics and PHYS 5602 Physics of Elementary Particles with a grade of B+ or higher in each.
Medical physics accelerated pathway: students must complete PHYS 5002 Computational Physics and PHYS 5313 Physical Applications of Fourier Analysis with a grade of B+ or higher in each.
Students may receive advanced standing with transfer of credit of up to 1.0 credit which will reduce their time to completion.
Admission
An M.Sc. in Physics or a closely related field is normally required for admission into the Ph.D. program.
Students who have been admitted to the M.Sc. program may be permitted to transfer into the Ph.D. program if they demonstrate academic abilities for advanced research in their field.
In exceptional cases, an outstanding student who has completed the honours B.Sc. will be considered.