Atmospheric Science and Physics Major (B.Sc.) (67 credits)
Offered by: Atmospheric & Oceanic Sciences (Faculty of Science)
Degree: Bachelor of Science
Program credit weight: 67
Program Description
(66-67 credits)
The B.Sc.; Major in Atmospheric Science and Physics provides a solid study in meteorology, atmospheric physics, or related fields.
The program is jointly offered by the Department of Physics and the Department of Atmospheric and Oceanic Sciences. Students should consult undergraduate advisers in both departments.
Degree Requirements — B.Sc.
This program is offered as part of a Bachelor of Science (B.Sc.) degree.
To graduate, students must satisfy both their program requirements and their degree requirements.
- The program requirements (i.e., the specific courses that make up this program) are listed under the Course Tab (above).
- The degree requirements—including the mandatory Foundation program, appropriate degree structure, and any additional components—are outlined on the Degree Requirements page.
Students are responsible for ensuring that this program fits within the overall structure of their degree and that all degree requirements are met. Consult the Degree Planning Guide on the SOUSA website for additional guidance.
Note: For information about Fall 2025 and Winter 2026 course offerings, please check back on May 8, 2025. Until then, the "Terms offered" field will appear blank for most courses while the class schedule is being finalized.
Required Courses (54 credits)
| Course | Title | Credits |
|---|---|---|
| ATOC 214 | Introduction: Physics of the Atmosphere. | 3 |
Introduction: Physics of the Atmosphere. Terms offered: this course is not currently offered. An introduction to key physical processes operating in the atmosphere, designed for students in science and engineering. Topics typically include: composition of the atmosphere; vertical structure; heat transfer; solar and terrestrial radiation and Earth's energy balance; seasonal and daily temperature changes; humidity and the formation of clouds and precipitation; stability of tropospheric air layers; applications of adiabatic charts. | ||
| ATOC 215 | Oceans, Weather and Climate. | 3 |
Oceans, Weather and Climate. Terms offered: this course is not currently offered. An introduction to key physical and dynamical processes in the oceans and atmosphere. Topics typically include air-sea-ice interactions, laws of motion, the geostrophic and thermal wind relations, general circulation of the atmosphere and oceans, weather, radiative balance, climate sensitivity and variability, role of the atmosphere and oceans in climate. | ||
| ATOC 309 | Weather Radars and Satellites. | 3 |
Weather Radars and Satellites. Terms offered: this course is not currently offered. Basic notions of radiative transfer and applications of satellite and radar data to mesoscale and synoptic-scale systems are discussed. Emphasis will be put on the contribution of remote sensing to atmospheric and oceanic sciences. | ||
| ATOC 312 | Rotating Fluid Dynamics. | 3 |
Rotating Fluid Dynamics. Terms offered: this course is not currently offered. Fundamentals of fluid motion on a rotating sphere: Rotating coordinate systems, the Lagrangian time derivative, and equations of motion. The geostrophic approximation and thermal wind balance; departures from geostrophy, such as frictional Ekman layers, inertial oscillations, and the gradient wind balance. The shallow water equations, including potential vorticity conservation, quasigeostrophy, and simple wave solutions. | ||
| ATOC 315 | Thermodynamics and Convection. | 3 |
Thermodynamics and Convection. Terms offered: this course is not currently offered. Buoyancy, stability, and vertical oscillations. Dry and moist adiabatic processes. Resulting dry and precipitating convective circulations from the small scale to the global scale. Mesoscale precipitation systems from the cell to convective complexes. Severe convection, downbursts, mesocyclones. | ||
| COMP 208 | Computer Programming for Physical Sciences and Engineering . | 3 |
Computer Programming for Physical Sciences and Engineering . Terms offered: this course is not currently offered. Programming and problem solving in a high level computer language: variables, expressions, types, functions, conditionals, loops, objects and classes. Introduction to algorithms such as searching and sorting. Modular software design, libraries, file input and output, debugging. Emphasis on applications in Physical Sciences and Engineering, such as root finding, numerical integration, diffusion, Monte Carlo methods. | ||
| MATH 222 | Calculus 3. | 3 |
Calculus 3. Terms offered: Summer 2025 Taylor series, Taylor's theorem in one and several variables. Review of vector geometry. Partial differentiation, directional derivative. Extreme of functions of 2 or 3 variables. Parametric curves and arc length. Polar and spherical coordinates. Multiple integrals. | ||
| MATH 223 | Linear Algebra. | 3 |
Linear Algebra. Terms offered: this course is not currently offered. Review of matrix algebra, determinants and systems of linear equations. Vector spaces, linear operators and their matrix representations, orthogonality. Eigenvalues and eigenvectors, diagonalization of Hermitian matrices. Applications. | ||
| MATH 314 | Advanced Calculus. | 3 |
Advanced Calculus. Terms offered: this course is not currently offered. Derivative as a matrix. Chain rule. Implicit functions. Constrained maxima and minima. Jacobians. Multiple integration. Line and surface integrals. Theorems of Green, Stokes and Gauss. Fourier series with applications. | ||
| MATH 315 | Ordinary Differential Equations. | 3 |
Ordinary Differential Equations. Terms offered: this course is not currently offered. First order ordinary differential equations including elementary numerical methods. Linear differential equations. Laplace transforms. Series solutions. | ||
| PHYS 230 | Dynamics of Simple Systems. | 3 |
Dynamics of Simple Systems. Terms offered: this course is not currently offered. Translational motion under Newton's laws; forces, momentum, work/energy theorem. Special relativity; Lorentz transforms, relativistic mechanics, mass/energy equivalence. Topics in rotational dynamics. Noninertial frames. | ||
| PHYS 232 | Heat and Waves. | 3 |
Heat and Waves. Terms offered: this course is not currently offered. The laws of thermodynamics and their consequences. Thermodynamics of P-V-T systems and simple heat engines. Free, driven, and damped harmonic oscillators. Coupled systems and normal modes. Fourier methods. Wave motion and dispersion. The wave equation. | ||
| PHYS 241 | Signal Processing. | 3 |
Signal Processing. Terms offered: this course is not currently offered. Linear circuit elements, resonance, network theorems, diodes, transistors, amplifiers, feedback, integrated circuits. | ||
| PHYS 257 | Experimental Methods 1. | 3 |
Experimental Methods 1. Terms offered: this course is not currently offered. Introductory laboratory work and data analysis as related to mechanics, optics and thermodynamics. Introduction to computers as they are employed for laboratory work, for data analysis and for numerical computation. Previous experience with computers is an asset, but is not required. | ||
| PHYS 333 | Thermal and Statistical Physics. | 3 |
Thermal and Statistical Physics. Terms offered: this course is not currently offered. Introductory equilibrium statistical mechanics. Quantum states, probabilities, ensemble averages. Entropy, temperature, Boltzmann factor, chemical potential. Photons and phonons. Fermi-Dirac and Bose-Einstein distributions; applications. | ||
| PHYS 340 | Majors Electricity and Magnetism. | 3 |
Majors Electricity and Magnetism. Terms offered: this course is not currently offered. The electrostatic field and scalar potential. Dielectric properties of matter. Energy in the electrostatic field. Methods for solving problems in electrostatics. The magnetic field. Induction and inductance. Energy in the magnetic field. Magnetic properties of matter. Maxwell's equations. The dipole approximation. | ||
| PHYS 342 | Majors Electromagnetic Waves. | 3 |
Majors Electromagnetic Waves. Terms offered: this course is not currently offered. Maxwell's equations. The wave equation. The electromagnetic wave, reflection, refraction, polarization. Guided waves. Transmission lines and wave guides. Vector potential. Radiation. The elemental dipole; the half-wave dipole; vertical dipole; folded dipoles; Yagi antennas. Accelerating charged particles. | ||
| PHYS 346 | Majors Quantum Physics. | 3 |
Majors Quantum Physics. Terms offered: this course is not currently offered. De Broglie waves, Bohr atom. Schroedinger equation, wave functions, observables. One dimensional potentials. Schroedinger equation in three dimensions. Angular momentum, hydrogen atom. Spin, experimental consequences. | ||
Complementary Courses (12-13 credits)
3 credits selected from:
| Course | Title | Credits |
|---|---|---|
| ATOC 357 | Atmospheric and Oceanic Science Laboratory. | 3 |
Atmospheric and Oceanic Science Laboratory. Terms offered: this course is not currently offered. Students will gain hands-on experience in several fundamental atmospheric and oceanic science topics through practical experimentation. A diverse set of experiments will be conducted, ranging from in situ observations in Montreal, to remote sensing of clouds and radiation, to laboratory chemistry and water-tank experiments. As a background for these experiments, students will receive training on sensor principles and measurement error analysis, as well as the fundamental physical processes of interest in each experiment. They will learn to operate, and physically interpret data from, various sensors for in situ and remote observation of meteorological variables. Their training will also extend to operational weather observations, analysis, and forecasting. | ||
| PHYS 258 | Experimental Methods 2. | 3 |
Experimental Methods 2. Terms offered: this course is not currently offered. Advanced laboratory work and data analysis as related to mechanics, optics and thermodynamics. Computers will be employed routinely for data analysis and for numerical computation, and, particularly, to facilitate the use of Fourier methods. | ||
9-10 credits selected from:
| Course | Title | Credits |
|---|---|---|
| ATOC 357 | Atmospheric and Oceanic Science Laboratory. | 3 |
Atmospheric and Oceanic Science Laboratory. Terms offered: this course is not currently offered. Students will gain hands-on experience in several fundamental atmospheric and oceanic science topics through practical experimentation. A diverse set of experiments will be conducted, ranging from in situ observations in Montreal, to remote sensing of clouds and radiation, to laboratory chemistry and water-tank experiments. As a background for these experiments, students will receive training on sensor principles and measurement error analysis, as well as the fundamental physical processes of interest in each experiment. They will learn to operate, and physically interpret data from, various sensors for in situ and remote observation of meteorological variables. Their training will also extend to operational weather observations, analysis, and forecasting. | ||
| ATOC 404 | Climate Physics. 1 | 3 |
Climate Physics. Terms offered: this course is not currently offered. This course covers the essentials of climate physics through the lens of one-dimensional, vertical atmospheric models. This includes shortwave and longwave radiative transfer, convection, phase changes, clouds, greenhouse gases, and atmospheric escape. This is an adequate level of detail for understanding Earth's climate, paleoclimate, anthropogenic climate change, or pursuing studies of Solar System planets and extrasolar planets. | ||
| ATOC 480 | Honours Research Project. | 3 |
Honours Research Project. Terms offered: Summer 2025 The student will carry out a research project under the supervision of a member of the staff. The student will be expected to write a report and present a seminar on the work. | ||
| ATOC 512 | Atmospheric and Oceanic Dynamics. | 3 |
Atmospheric and Oceanic Dynamics. Terms offered: this course is not currently offered. Equations of motion used to study waves, turbulence, and the general circulation of the atmosphere and oceans. Standard approximations to these equations, including the Boussinesq, primitive, quasigeostrohic, and rotating shallow water equations. Emphasis is on effects for which rotation and/or buoyancy play essential roles. Simple classes of flow, e.g., geostrophic, thermal wind, Ekman, and inertial oscillations. | ||
| ATOC 513 | Waves and Stability. | 3 |
Waves and Stability. Terms offered: this course is not currently offered. Description of the principal wave types and instability mechanisms of geophysical fluid dynamics. Geostrophic adjustment, wave dispersion, the WKBJ approximation. Wave types considered include (internal) inertia-gravity waves, planetary Rossby waves, and the equatorial and coastal wave guides. Instabilities considered include inertial, symmetric, barotropic, baroclinic, and Kelvin-Helmholtz instability. | ||
| ATOC 515 | Turbulence in Atmosphere and Oceans. | 3 |
Turbulence in Atmosphere and Oceans. Terms offered: this course is not currently offered. Application of statistical and semi-empirical methods to the study of geophysical turbulence. Reynolds' equations, dimensional analysis, and similarity. The surface and planetary boundary layers. Oceanic mixed layer. Theories of isotropic two- and three- dimensional turbulence: energy and enstrophy inertial ranges. Beta turbulence. | ||
| ATOC 517 | Boundary Layer Meteorology . | 3 |
Boundary Layer Meteorology . Terms offered: this course is not currently offered. Turbulence and turbulent fluxes, atmospheric stability, Monin-Obukhov similarity theory, surface roughness and surface fluxes, power law and logarithmic wind profiles including their application in wind energy and engineering sectors, convective and stably stratified boundary layers, internal boundary layer development, large-eddy simulations, fundamentals of boundary-layer parameterization in numerical models, and introduction to urban boundary layers. | ||
| ATOC 521 | Cloud Physics. | 3 |
Cloud Physics. Terms offered: this course is not currently offered. A detailed overview of the environmental factors and microphysical processes involved in the formation of clouds and precipitation. Topics typically include: cloud observations, atmospheric thermodynamics, environmental stability regimes, convection, the microphysics of the formation of cloud droplets and ice crystals, initiation of precipitation, aerosol–cloud interactions. | ||
| ATOC 525 | Atmospheric Radiation. | 3 |
Atmospheric Radiation. Terms offered: this course is not currently offered. Solar and terrestrial radiation. Interactions of molecules, aerosols, clouds, and precipitation with radiation of various wavelengths. Radiative transfer through the clear and cloudy atmosphere. Radiation budgets. Satellite and ground-based measurements. Climate implications. | ||
| ATOC 531 | Dynamics of Current Climates. | 3 |
Dynamics of Current Climates. Terms offered: this course is not currently offered. A detailed overview of the climate and the global energy balance. Topics typically include: energy balance at top of the atmosphere and at the surface, poleward energy flux, the role of clouds, climate and atmospheric/oceanic general circulations, natural variability of the climate system, evolution of climate and climate change. | ||
| ATOC 540 | Synoptic Meteorology 1. | 3 |
Synoptic Meteorology 1. Terms offered: this course is not currently offered. Analysis of current meteorological data. Description of a geostrophic, hydrostatic atmosphere. Ageostrophic circulations and hydrostatic instabilities. Kinematic and thermodynamic methods of computing vertical motions. Tropical and extratropical condensation rates. Barotropic and equivalent barotropic atmospheres. | ||
| ATOC 541 | Synoptic Meteorology 2. | 3 |
Synoptic Meteorology 2. Terms offered: this course is not currently offered. Analysis of current meteorological data. Quasi-geostrophic theory, including the omega equation, as it relates to extratropical cyclone and anticyclone development. Frontogenesis and frontal circulations in the lower and upper troposphere. Cumulus convection and its relationship to tropical and extratropical circulations. Diagnostic case study work. | ||
| ATOC 548 | Mesoscale Meteorology. | 3 |
Mesoscale Meteorology. Terms offered: this course is not currently offered. Theory of meteorologically important mesoscale phenomena including mesoscale instabilities, cumulus convection and its organization (including thunderstorms, squall lines, and other forms of severe weather), internal gravity waves, and topographically forced flows. Application of theory to the physical interpretation of observations and numerical simulations. | ||
| ATOC 557 | Research Methods: Atmospheric and Oceanic Science. | 3 |
Research Methods: Atmospheric and Oceanic Science. Terms offered: this course is not currently offered. The analysis of observational and modeling data, and the advantages and limitations of different data. Different analysis methods including regression, linear stochastic processes autocovariance and spectral analysis, principle component analysis, inverse problems and data assimilation, commonly used in the atmospheric and oceanic sciences. | ||
| ATOC 558 | Numerical Methods and Laboratory. | 3 |
Numerical Methods and Laboratory. Terms offered: this course is not currently offered. Numerical simulation of atmospheric and oceanic processes. Finite difference, finite element, and spectral modelling techniques. Term project including computer modelling of convection or large-scale flows in the atmosphere or ocean. | ||
| ATOC 568 | Ocean Physics. | 3 |
Ocean Physics. Terms offered: this course is not currently offered. Major topics in physics and dynamics of the ocean including seawater properties, density and equation of state, sea ice, air-sea-ice exchanges, mixing and stability in the ocean, wind-driven and thermohaline circulations. Observational techniques and numerical models of the ocean, which include some data analysis and literature review. | ||
| COMP 551 | Applied Machine Learning. | 4 |
Applied Machine Learning. Terms offered: this course is not currently offered. Selected topics in machine learning and data mining, including clustering, neural networks, support vector machines, decision trees. Methods include feature selection and dimensionality reduction, error estimation and empirical validation, algorithm design and parallelization, and handling of large data sets. Emphasis on good methods and practices for deployment of real systems. | ||
| PHYS 331 | Topics in Classical Mechanics. | 3 |
Topics in Classical Mechanics. Terms offered: this course is not currently offered. Forced and damped oscillators, Newtonian mechanics in three dimensions, rotational motion, Lagrangian and Hamiltonian mechanics, small vibrations, normal modes. Nonlinear dynamics and chaos. | ||
| PHYS 339 | Measurements Laboratory in General Physics. | 3 |
Measurements Laboratory in General Physics. Terms offered: this course is not currently offered. Introduction to modern techniques of measurement. The use of computers in performing and analysing experiments. Data reduction, statistical methods, report writing. Extensive use of computers is made in this laboratory; therefore some familiarity with computers and computing is an advantage. | ||
| PHYS 404 | Climate Physics. 1 | 3 |
Climate Physics. Terms offered: this course is not currently offered. This course covers the essentials of climate physics through the lens of one-dimensional, vertical atmospheric models. This includes shortwave and longwave radiative transfer, convection, phase changes, clouds, greenhouse gases, and atmospheric escape. This is an adequate level of detail for understanding Earth's climate, paleoclimate, anthropogenic climate change, or pursing studies of Solar System planets and extrasolar planets. | ||
| PHYS 432 | Physics of Fluids. | 3 |
Physics of Fluids. Terms offered: this course is not currently offered. The physical properties of fluids. The kinematics and dynamics of flow. The effects of viscosity and turbulence. Applications of fluid mechanics in biophysics, geophysics and engineering. | ||
| PHYS 434 | Optics. | 3 |
Optics. Terms offered: this course is not currently offered. Fundamental concepts of optics, including applications and modern developments. Light propagation in media; geometric optics and optical instruments; polarization and coherence properties of light; interference and interferometry; diffraction theory and applications in spectrometry and imaging; Gaussian beams, Fourier optics and photonic band structure. A laboratory component provides hands-on experience in optical setup design, construction and testing of concepts introduced in lectures. | ||
| PHYS 449 | Majors Research Project. | 3 |
Majors Research Project. Terms offered: this course is not currently offered. A supervised research project. | ||
| PHYS 512 | Computational Physics with Applications. | 3 |
Computational Physics with Applications. Terms offered: this course is not currently offered. Computational methods in Physics illustrated with realworld applications. | ||