Honour Programs in Atmospheric Science

Atmospheric & Oceanic Sciences: An introduction to physical meteorology designed for students in the physical sciences. Topics include: composition of the atmosphere; heat transfer; the upper atmosphere; atmospheric optics; formation of clouds and precipitation; instability; adiabatic charts.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisite: CEGEP Physics, or the combination of PHYS 131 and PHYS 142, or permission of instructor.

• Terms
  • Fall 2013
• Instructors
  • Yi Huang

Atmospheric & Oceanic Sciences: Laws of motion, geostrophic wind, gradient wind. General circulation of the atmosphere and oceans, local circulation features. Air-sea interaction, including hurricanes and sea-ice formation, extra-tropical weather systems and fronts, role of the atmosphere and oceans in climate.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite: ATOC 214

• Terms
  • Winter 2014
• Instructors
  • Man K Yau

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite: ATOC 215

• Terms
  • Winter 2014
• Instructors
  • Frederic Fabry, Gerard Szejwach

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisites: ATOC 214 and MATH 222

• Terms
  • Fall 2013
• Instructors
  • Gerard Szejwach

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Restriction: U3 Honours students

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: Introduction to the fluid dynamics of large-scale flows of the atmosphere and oceans. Stratification of atmosphere and oceans. Equations of state, thermodynamics and momentum. Kinematics, circulation, and vorticity. Hydrostatic and quasi-geostrophic flows. Brief introduction to wave motions, flow over topography, Ekman boundary layers, turbulence.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 314, MATH 315, or permission of instructor

• Terms
  • Fall 2013
• Instructors
  • Peter Bartello

Atmospheric & Oceanic Sciences: The general circulation of the atmosphere and oceans. Atmospheric and oceanic general circulation models. Observations and models of the El Niño and Southern Oscillation phenomena.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 315 or permission of instructor
• Corequisite (Undergraduate): ATOC 412 or ATOC 512 or permission of instructor

• Terms
  • Winter 2014
• Instructors
  • Bruno Tremblay

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 2 hours lecture; 2 hours laboratory
• Prerequisite (Undergraduate): MATH 314, MATH 315, or permission of instructor

• Terms
  • Fall 2013
• Instructors
  • Eyad Hashem Atallah

Atmospheric & Oceanic Sciences: Half-hour briefing on atmospheric general circulation and current weather around the world using satellite data, radar observations, conventional weather maps, and analyses and forecasts produced by computer techniques.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 2 hours
• Prerequisite (Undergraduate): ATOC 540 or permission of instructor
• Restriction: Graduate students and final-year Honours Atmospheric Science students. Others by special permission.

• Terms
  • Winter 2014
• Instructors
  • Eyad Hashem Atallah

Computer Science (Sci): Introduction to computer systems. Concepts and structures for high level programming. Elements of structured programming using FORTRAN 90 and C. Numerical algorithms such as root finding, numerical integration and differential equations. Non-numerical algorithms for sorting and searching.

Offered by: Computer Science

• 3 hours
• Prerequisite: differential and integral calculus.
• Corequisite: linear algebra: determinants, vectors, matrix operations.
• Restrictions: COMP 202 and COMP 208 cannot both be taken for credit. COMP 202 is intended as a general introductory course, while COMP 208 is intended for students interested in scientific computations. Credits for either of these courses will not count towards the 60-credit Major in Computer Science. COMP 208 cannot be taken for credit with or after COMP 250.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Nathan Friedman, Wenbo He
  • Nathan Friedman

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Prerequisite: MATH 141. Familiarity with vector geometry or Corequisite: MATH 133
• Restriction: Not open to students who have taken CEGEP course 201-303 or MATH 150, MATH 151 or MATH 227

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Payman L Kassaei, Wilbur Jonsson
  • Wilbur Jonsson

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Fall and Winter
• Prerequisite: MATH 133 or equivalent
• Restriction: Not open to students in Mathematics programs nor to students who have taken or are taking MATH 236, MATH 247 or MATH 251. It is open to students in Faculty Programs

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Wilbur Jonsson
  • Wilbur Jonsson

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Prerequisites: MATH 133, MATH 222
• Restriction: Not open to students who have taken or are taking MATH 248

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Ivo Klemes

Mathematics & Statistics (Sci): First order ordinary differential equations including elementary numerical methods. Linear differential equations. Laplace transforms. Series solutions.

Offered by: Mathematics and Statistics

• Prerequisite: MATH 222.
• Corequisite: MATH 133.
• Restriction: Not open to students who have taken or are taking MATH 325.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Charles Roth
  • Gantumur Tsogtgerel

Mathematics & Statistics (Sci): First order equations, geometric theory; second order equations, classification; Laplace, wave and heat equations, Sturm-Liouville theory, Fourier series, boundary and initial value problems.

Offered by: Mathematics and Statistics

• Winter
• Prerequisites: MATH 223 or MATH 236, MATH 314, MATH 315

• Terms
  • Winter 2014
• Instructors
  • Peter Bartello

Physics: 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.

Offered by: Physics

• Fall
• 3 hours lectures
• Prerequisite: CEGEP Physics or PHYS 131.
• Corequisite: MATH 222
• Restriction: Not open to students taking or having passed PHYS 251

• Terms
  • Fall 2013
• Instructors
  • Tamar Pereg-Barnea

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisites: CEGEP Physics or PHYS 142, and CEGEP chemistry or CHEM 120, and PHYS 230.
• Restriction: Not open to students taking or having passed PHYS 253

• Terms
  • Winter 2014
• Instructors
  • Dominic Ryan, Hong Guo

Physics: 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.

Offered by: Physics

• Fall
• 6 hours of laboratory and classroom work
• Corequisite: PHYS 230 or PHYS 251

• Terms
  • Fall 2013
• Instructors
  • Andreas T Warburton

Mathematics & Statistics (Sci): Examples of statistical data and the use of graphical means to summarize the data. Basic distributions arising in the natural and behavioural sciences. The logical meaning of a test of significance and a confidence interval. Tests of significance and confidence intervals in the one and two sample setting (means, variances and proportions).

Offered by: Mathematics and Statistics

• No calculus prerequisites
• Restriction: This course is intended for students in all disciplines. For extensive course restrictions covering statistics courses see Section 3.6.1 of the Arts and of the Science sections of the calendar regarding course overlaps.
• You may not be able to receive credit for this course and other statistic courses. Be sure to check the Course Overlap section under Faculty Degree Requirements in the Arts or Science section of the Calendar. Students should consult http://www.mcgill.ca/student-records/transfercredits/ for information regarding transfer credits for this course.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Christian Genest
  • David B Wolfson

Mathematics & Statistics (Sci): Sample space, events, conditional probability, independence of events, Bayes' Theorem. Basic combinatorial probability, random variables, discrete and continuous univariate and multivariate distributions. Independence of random variables. Inequalities, weak law of large numbers, central limit theorem.

Offered by: Mathematics and Statistics

• Prerequisites: MATH 141 or equivalent.
• Restriction: Intended for students in Science, Engineering and related disciplines, who have had differential and integral calculus
• Restriction: Not open to students who have taken or are taking MATH 356

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Masoud Asgharian-Dastenaei
  • William J Anderson

Mathematics & Statistics (Sci): Sampling distributions, point and interval estimation, hypothesis testing, analysis of variance, contingency tables, nonparametric inference, regression, Bayesian inference.

Offered by: Mathematics and Statistics

• Fall and Winter
• Prerequisite: MATH 323 or equivalent
• Restriction: Not open to students who have taken or are taking MATH 357
• You may not be able to receive credit for this course and other statistic courses. Be sure to check the Course Overlap section under Faculty Degree Requirements in the Arts or Science section of the Calendar.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • William J Anderson
  • Masoud Asgharian-Dastenaei

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisite: PHYS 232
• Restriction: Not open to students taking or having passed PHYS 362

• Terms
  • Winter 2014
• Instructors
  • Sabrina Leslie

Physics: 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.

Offered by: Physics

• Fall
• 3 hours lectures
• Prerequisites: CEGEP physics or PHYS 142, MATH 222
• Corequisite: MATH 314
• Restriction: Not open to students who have passed PHYS 242 or PHYS 350

• Terms
  • Fall 2013
• Instructors
  • Shaun MacDonald Lovejoy

Atmospheric & Oceanic Sciences: Selected areas of atmospheric chemistry from field and laboratory to theoretical modelling are examined. The principles of atmospheric reactions (gas, liquid and heterogeneous phases in aerosols and clouds) and issues related to chemical global change will be explored.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisites: CHEM 243, and CHEM 263 or CHEM 213 and CHEM 273, MATH 222 and MATH 315 (or equivalents) or permission of instructor.
• Restriction: Not open to students who have taken CHEM 419, CHEM 619, and ATOC 619
• Offered in odd years. Students should register in CHEM 419 in even years

• Symbols:
• Taught only in alternate years

• Terms
  • Winter 2014
• Instructors
  • Parisa A Ariya

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 314, MATH 315, a previous course in fluid dynamics (such as ATOC 512), or permission of instructor

• Symbols:
• Taught only in alternate years

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Chemistry: Selected areas of atmospheric chemistry from field and laboratory to theoretical modelling are examined. The principles of atmospheric reactions (gas, liquid and heterogeneous phases in aerosols and clouds) and issues related to chemical global change will be explored.

Offered by: Chemistry

• Winter
• 3 lectures
• Prerequisites: CHEM 243, and CHEM 263 or CHEM 213 and CHEM 273, MATH 222 and MATH 315 (or equivalents) or permission of instructor.
• Restriction: Not open to students who have taken ATOC 419, CHEM 619, or ATOC 619
• Offered in even years. Students should register in ATOC 419 in odd years.

• Symbols:
• Taught only in alternate years

• Terms
  • Winter 2014
• Instructors
  • Parisa A Ariya

Geography: Quantitative, experimental study of the principles governing the movement of water at or near the Earth's surface and how the research relates to the chemistry and biology of ecosystems.

Offered by: Geography

• Winter
• 3 hours
• Prerequisite: GEOG 203 or equivalent

• Terms
  • Winter 2014
• Instructors
  • Nigel Thomas Roulet, Bernhard L Lehner

Geography: The course focuses on the physical habitat conditions found in streams, rivers, estuaries and deltas. Based on the laws governing flow of water and sediment transport, it emphasizes differences among these environments, in terms of channel form, flow patterns, substrate composition and mode of evolution. Flooding, damming, channelisation, forestry impacts.

Offered by: Geography

• Fall
• 3 hours
• Prerequisites: GEOG 203 and GEOG 272, or ENVR 200 and ENVR 202

• Terms
  • Fall 2013
• Instructors
  • Michel F Lapointe

Mathematics & Statistics (Sci): Error analysis. Numerical solutions of equations by iteration. Interpolation. Numerical differentiation and integration. Introduction to numerical solutions of differential equations.

Offered by: Mathematics and Statistics

• Fall
• Prerequisites: MATH 315 or MATH 325 or MATH 263, and COMP 202 or permission of instructor.

• Terms
  • Fall 2013
• Instructors
  • Peter Bartello

Mathematics & Statistics (Sci): Least-squares estimators and their properties. Analysis of variance. Linear models with general covariance. Multivariate normal and chi-squared distributions; quadratic forms. General linear hypothesis: F-test and t-test. Prediction and confidence intervals. Transformations and residual plot. Balanced designs.

Offered by: Mathematics and Statistics

• Fall
• Prerequisites: MATH 324, and MATH 223 or MATH 236
• Restriction: Not open to students who have taken or are taking MATH 533.

• Terms
  • Fall 2013
• Instructors
  • Abbas Khalili Mahmoudabadi

Mathematics & Statistics (Sci): Kinematics. Dynamics of general fluids. Inviscid fluids, Navier-Stokes equations. Exact solutions of Navier-Stokes equations. Low and high Reynolds number flow.

Offered by: Mathematics and Statistics

• Fall
• Prerequisite (Undergraduate): MATH 315 and MATH 319 or equivalent

• Symbols:
• Taught only in alternate years

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Physics: Linear circuit elements, resonance, network theorems, diodes, transistors, amplifiers, feedback, integrated circuits.

Offered by: Physics

• Winter
• 2 hours lectures; 3 hours laboratory alternate weeks
• Prerequisite: CEGEP physics or PHYS 142.

• Terms
  • Winter 2014
• Instructors
  • Mark Sutton, Matthew Adam Dobbs

Physics: Forced and damped oscillators, Newtonian mechanics in three dimensions, rotational motion, Lagrangian mechanics, small vibrations, normal modes. Introduction to Hamiltonian mechanics.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisite: PHYS 230
• Corequisite: MATH 315
• Restriction: Not open to students having passed PHYS 451 or PHYS 351

• Terms
  • Winter 2014
• Instructors
  • Gilbert P Holder

Physics: 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.

Offered by: Physics

• Fall
• 3 hours lectures
• Prerequisites: CEGEP physics or PHYS 142, MATH 222
• Corequisite: MATH 314
• Restriction: Not open to students who have passed PHYS 242 or PHYS 350

• Terms
  • Fall 2013
• Instructors
  • Shaun MacDonald Lovejoy

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisites: PHYS 340 or PHYS 242, Mathematics MATH 314, MATH 315

• Terms
  • Winter 2014
• Instructors
  • Michael Hilke

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisites: PHYS 230, MATH 223, MATH 314, MATH 315
• Restriction: Not open to students who have taken PHYS 332.

• Terms
  • Winter 2014
• Instructors
  • James M Cline

Atmospheric & Oceanic Sciences: Linear theory of waves in rotating and stratified media. Geostrophic adjustment and model initialization. Wave propagation in slowly varying media. Mountain waves; waves in shear flows. Barotropic, baroclinic, symmetric, and Kelvin-Helmholtz instability. Wave-mean flow interaction. Equatorially trapped waves.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 314, MATH 315, or permission of instructor

• Terms
  • Winter 2014
• Instructors
  • David N Straub

Atmospheric & Oceanic Sciences: Review of dry and moist atmospheric thermodynamics concepts. Atmospheric aerosols, nucleation of water and ice. Formation and growth of cloud droplets and ice crystals. Initiation of precipitation. Severe storms and hail. Weather modification. Numerical cloud models.

Offered by: Atmospheric & Oceanic Sciences

• 3 hours
• Prerequisites (Undergraduates): ATOC 315, MATH 314, and MATH 315, or permission of instructor.
• Restriction: Not open to students who have taken ATOC 621.

• Terms
  • Fall 2013
• Instructors
  • Man K Yau

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Prerequisites (Undergraduates): ATOC 315, MATH 314, and MATH 315, or permission of instructor.
• Restriction: Not open to students who have taken ATOC 620.

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: Introduction to the components of the climate system. Review of paleoclimates. Physical processes and models of climate and climate change.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 315, or permission of instructor

• Symbols:
• Taught only in alternate years

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 2 hours lecture; 2 hours laboratory
• Prerequisite (Undergraduate): ATOC 412 and ATOC 540 or permission of instructor.

• Terms
  • Winter 2014
• Instructors
  • Eyad Hashem Atallah

Atmospheric & Oceanic Sciences: An introduction to physical meteorology designed for students in the physical sciences. Topics include: composition of the atmosphere; heat transfer; the upper atmosphere; atmospheric optics; formation of clouds and precipitation; instability; adiabatic charts.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisite: CEGEP Physics, or the combination of PHYS 131 and PHYS 142, or permission of instructor.

• Terms
  • Fall 2013
• Instructors
  • Yi Huang

Atmospheric & Oceanic Sciences: Laws of motion, geostrophic wind, gradient wind. General circulation of the atmosphere and oceans, local circulation features. Air-sea interaction, including hurricanes and sea-ice formation, extra-tropical weather systems and fronts, role of the atmosphere and oceans in climate.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite: ATOC 214

• Terms
  • Winter 2014
• Instructors
  • Man K Yau

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite: ATOC 215

• Terms
  • Winter 2014
• Instructors
  • Frederic Fabry, Gerard Szejwach

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisites: ATOC 214 and MATH 222

• Terms
  • Fall 2013
• Instructors
  • Gerard Szejwach

Atmospheric & Oceanic Sciences: Equations of motion in rotating coordinates, elementary applications, circulation and vorticity, the planetary boundary layer, synoptic scale motions, Rossby waves and inertial oscillations.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• Prerequisites: MATH 314, MATH 315, and PHYS 230.

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: Selected areas of atmospheric chemistry from field and laboratory to theoretical modelling are examined. The principles of atmospheric reactions (gas, liquid and heterogeneous phases in aerosols and clouds) and issues related to chemical global change will be explored.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisites: CHEM 243, and CHEM 263 or CHEM 213 and CHEM 273, MATH 222 and MATH 315 (or equivalents) or permission of instructor.
• Restriction: Not open to students who have taken CHEM 419, CHEM 619, and ATOC 619
• Offered in odd years. Students should register in CHEM 419 in even years

• Symbols:
• Taught only in alternate years

• Terms
  • Winter 2014
• Instructors
  • Parisa A Ariya

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Restriction: U3 Honours students

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: The general circulation of the atmosphere and oceans. Atmospheric and oceanic general circulation models. Observations and models of the El Niño and Southern Oscillation phenomena.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 315 or permission of instructor
• Corequisite (Undergraduate): ATOC 412 or ATOC 512 or permission of instructor

• Terms
  • Winter 2014
• Instructors
  • Bruno Tremblay

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Fall
• 2 hours lecture; 2 hours laboratory
• Prerequisite (Undergraduate): MATH 314, MATH 315, or permission of instructor

• Terms
  • Fall 2013
• Instructors
  • Eyad Hashem Atallah

Atmospheric & Oceanic Sciences: Half-hour briefing on atmospheric general circulation and current weather around the world using satellite data, radar observations, conventional weather maps, and analyses and forecasts produced by computer techniques.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 2 hours
• Prerequisite (Undergraduate): ATOC 540 or permission of instructor
• Restriction: Graduate students and final-year Honours Atmospheric Science students. Others by special permission.

• Terms
  • Winter 2014
• Instructors
  • Eyad Hashem Atallah

Chemistry: Kinetics 1: Gas laws, kinetic theory of collisions. Thermodynamics: Zeroth law of thermodynamics. First law of thermodynamics, heat capacity, enthalpy, thermochemistry, bond energies. Second law of thermodynamics; the entropy and free energy functions. Third law of thermodynamics, absolute entropies, free energies, Maxwell relations and chemical and thermodynamic equilibrium states.

Offered by: Chemistry

• Fall
• Prerequisites: CHEM 110, CHEM 120 or equivalent, PHYS 142, or permission of instructor.
• Corequisite: MATH 222 or equivalent.
• Restrictions: Not open to students who have taken or are taking CHEM 203 or CHEM 204.
• Note: Chemistry Honours and Majors must take CHEM 223 and CHEM 253 simultaneously.

• Terms
  • Fall 2013
• Instructors
  • David M Ronis

Chemistry: Heterogeneous equilibrium: phase rule and phase diagrams. Ideal solutions, colligative properties, solubility. Electrochemistry, Debye-Hückel Theory. Kinetics 2: Transition State Theory, complex reactions, free-radical reactions, chain reactions, catalysis, reactions at surfaces, ionic effects of reactions in solution, photochemistry.

Offered by: Chemistry

• Winter
• Prerequisites: CHEM 223 and CHEM 253.
• Restrictions: Not open to students who have taken or are taking CHEM 203 or CHEM 204. Permission of instructor.
• Note: Chemistry Honours and Majors must take CHEM 243 and CHEM 263 simultaneously.

• Terms
  • Winter 2014
• Instructors
  • Gonzalo Cosa

Chemistry: Illustrative experiments in physical chemistry. Laboratory section of CHEM 223.

Offered by: Chemistry

• Fall
• Prerequisite: CHEM 110, CHEM 120 or equivalent.
• Corequisite: CHEM 223 or equivalent or permission of instructor.

• Terms
  • Fall 2013
• Instructors
  • Amy S Blum, Jean-Marc Gauthier

Chemistry: Illustrative experiments in physical chemistry. Laboratory section of CHEM 243.

Offered by: Chemistry

• Winter
• Prerequisites: CHEM 223 and CHEM 253.
• Corequisite: CHEM 243 or equivalent.
• Restrictions: Not open to students who have taken or are taking CHEM 203 or CHEM 204. Permission of instructor.
• Note: Chemistry Honours and Majors must take CHEM 243 and CHEM 263 simultaneously.

• Terms
  • Winter 2014
• Instructors
  • Amy S Blum, Jean-Marc Gauthier

Chemistry: Selected areas of atmospheric chemistry from field and laboratory to theoretical modelling are examined. The principles of atmospheric reactions (gas, liquid and heterogeneous phases in aerosols and clouds) and issues related to chemical global change will be explored.

Offered by: Chemistry

• Winter
• 3 lectures
• Prerequisites: CHEM 243, and CHEM 263 or CHEM 213 and CHEM 273, MATH 222 and MATH 315 (or equivalents) or permission of instructor.
• Restriction: Not open to students who have taken ATOC 419, CHEM 619, or ATOC 619
• Offered in even years. Students should register in ATOC 419 in odd years.

• Symbols:
• Taught only in alternate years

• Terms
  • Winter 2014
• Instructors
  • Parisa A Ariya

Computer Science (Sci): Introduction to computer systems. Concepts and structures for high level programming. Elements of structured programming using FORTRAN 90 and C. Numerical algorithms such as root finding, numerical integration and differential equations. Non-numerical algorithms for sorting and searching.

Offered by: Computer Science

• 3 hours
• Prerequisite: differential and integral calculus.
• Corequisite: linear algebra: determinants, vectors, matrix operations.
• Restrictions: COMP 202 and COMP 208 cannot both be taken for credit. COMP 202 is intended as a general introductory course, while COMP 208 is intended for students interested in scientific computations. Credits for either of these courses will not count towards the 60-credit Major in Computer Science. COMP 208 cannot be taken for credit with or after COMP 250.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Nathan Friedman, Wenbo He
  • Nathan Friedman

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Prerequisite: MATH 141. Familiarity with vector geometry or Corequisite: MATH 133
• Restriction: Not open to students who have taken CEGEP course 201-303 or MATH 150, MATH 151 or MATH 227

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Payman L Kassaei, Wilbur Jonsson
  • Wilbur Jonsson

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Fall and Winter
• Prerequisite: MATH 133 or equivalent
• Restriction: Not open to students in Mathematics programs nor to students who have taken or are taking MATH 236, MATH 247 or MATH 251. It is open to students in Faculty Programs

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Wilbur Jonsson
  • Wilbur Jonsson

Mathematics & Statistics (Sci): 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.

Offered by: Mathematics and Statistics

• Prerequisites: MATH 133, MATH 222
• Restriction: Not open to students who have taken or are taking MATH 248

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Ivo Klemes

Mathematics & Statistics (Sci): First order ordinary differential equations including elementary numerical methods. Linear differential equations. Laplace transforms. Series solutions.

Offered by: Mathematics and Statistics

• Prerequisite: MATH 222.
• Corequisite: MATH 133.
• Restriction: Not open to students who have taken or are taking MATH 325.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Charles Roth
  • Gantumur Tsogtgerel

Mathematics & Statistics (Sci): First order equations, geometric theory; second order equations, classification; Laplace, wave and heat equations, Sturm-Liouville theory, Fourier series, boundary and initial value problems.

Offered by: Mathematics and Statistics

• Winter
• Prerequisites: MATH 223 or MATH 236, MATH 314, MATH 315

• Terms
  • Winter 2014
• Instructors
  • Peter Bartello

Physics: 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.

Offered by: Physics

• Fall
• 3 hours lectures
• Prerequisite: CEGEP Physics or PHYS 131.
• Corequisite: MATH 222
• Restriction: Not open to students taking or having passed PHYS 251

• Terms
  • Fall 2013
• Instructors
  • Tamar Pereg-Barnea

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisites: CEGEP Physics or PHYS 142, and CEGEP chemistry or CHEM 120, and PHYS 230.
• Restriction: Not open to students taking or having passed PHYS 253

• Terms
  • Winter 2014
• Instructors
  • Dominic Ryan, Hong Guo

Physics: 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.

Offered by: Physics

• Fall
• 6 hours of laboratory and classroom work
• Corequisite: PHYS 230 or PHYS 251

• Terms
  • Fall 2013
• Instructors
  • Andreas T Warburton

Mathematics & Statistics (Sci): Examples of statistical data and the use of graphical means to summarize the data. Basic distributions arising in the natural and behavioural sciences. The logical meaning of a test of significance and a confidence interval. Tests of significance and confidence intervals in the one and two sample setting (means, variances and proportions).

Offered by: Mathematics and Statistics

• No calculus prerequisites
• Restriction: This course is intended for students in all disciplines. For extensive course restrictions covering statistics courses see Section 3.6.1 of the Arts and of the Science sections of the calendar regarding course overlaps.
• You may not be able to receive credit for this course and other statistic courses. Be sure to check the Course Overlap section under Faculty Degree Requirements in the Arts or Science section of the Calendar. Students should consult http://www.mcgill.ca/student-records/transfercredits/ for information regarding transfer credits for this course.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • Christian Genest
  • David B Wolfson

Mathematics & Statistics (Sci): Sampling distributions, point and interval estimation, hypothesis testing, analysis of variance, contingency tables, nonparametric inference, regression, Bayesian inference.

Offered by: Mathematics and Statistics

• Fall and Winter
• Prerequisite: MATH 323 or equivalent
• Restriction: Not open to students who have taken or are taking MATH 357
• You may not be able to receive credit for this course and other statistic courses. Be sure to check the Course Overlap section under Faculty Degree Requirements in the Arts or Science section of the Calendar.

• Terms
  • Fall 2013
  • Winter 2014
• Instructors
  • William J Anderson
  • Masoud Asgharian-Dastenaei

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 314, MATH 315, a previous course in fluid dynamics (such as ATOC 512), or permission of instructor

• Symbols:
• Taught only in alternate years

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Chemistry: An introduction to modern instrumental analysis emphasizing chromatography, electrochemical methods and computational data analysis. Analytical methods to be examined in detail include gas-liquid and high performance liquid chromatography, LC mass spectrometry, and advanced electro-analysis techniques

Offered by: Chemistry

• Fall
• Prerequisite: CHEM 257 or CHEM 277 or CHEM 287 and CHEM 297.
• Each lab section is limited enrolment

• Terms
  • Fall 2013
• Instructors
  • Joan F Power, Joan F Power, Samuel Lewis Sewall, Jean-Marc Gauthier

Chemistry: Kinetic laws, measurement of reaction rates, transition state and collision theory, experimental techniques in reaction kinetics, reaction mechanisms, RRKM theory, Marcus theory of electron transfer, photochemistry and catalysis. Recent developments and their application to chemical and biological problems. Elementary reactions in gas, solution and solid phases and on surfaces.

Offered by: Chemistry

• Winter
• Prerequisites: CHEM 273 and CHEM 223/CHEM 243 (formerly CHEM 213).

• Terms
  • Fall 2013
• Instructors
  • Gonzalo Cosa

Earth & Planetary Sciences: History of chemical oceanography. Seawater composition and definition of salinity/chlorinity. Minor and trace-element distribution in the ocean. Geochemical mass balance. Dissolved gases in sea water. CO2 and the carbonate system. Chemical speciation. Physical chemistry of seawater. Organic matter and the carbon cycle in the marine environment. Sediment geochemistry.

Offered by: Earth & Planetary Sciences

• Fall
• 3 hours lectures
• Prerequisites: CHEM 213, CHEM 257 or equivalents, or registration in the Graduate Program in Oceanography.

• Terms
  • Fall 2013
• Instructors
  • Alfonso Mucci

Mathematics & Statistics (Sci): Error analysis. Numerical solutions of equations by iteration. Interpolation. Numerical differentiation and integration. Introduction to numerical solutions of differential equations.

Offered by: Mathematics and Statistics

• Fall
• Prerequisites: MATH 315 or MATH 325 or MATH 263, and COMP 202 or permission of instructor.

• Terms
  • Fall 2013
• Instructors
  • Peter Bartello

Mathematics & Statistics (Sci): Least-squares estimators and their properties. Analysis of variance. Linear models with general covariance. Multivariate normal and chi-squared distributions; quadratic forms. General linear hypothesis: F-test and t-test. Prediction and confidence intervals. Transformations and residual plot. Balanced designs.

Offered by: Mathematics and Statistics

• Fall
• Prerequisites: MATH 324, and MATH 223 or MATH 236
• Restriction: Not open to students who have taken or are taking MATH 533.

• Terms
  • Fall 2013
• Instructors
  • Abbas Khalili Mahmoudabadi

Physics: Linear circuit elements, resonance, network theorems, diodes, transistors, amplifiers, feedback, integrated circuits.

Offered by: Physics

• Winter
• 2 hours lectures; 3 hours laboratory alternate weeks
• Prerequisite: CEGEP physics or PHYS 142.

• Terms
  • Winter 2014
• Instructors
  • Mark Sutton, Matthew Adam Dobbs

Physics: Forced and damped oscillators, Newtonian mechanics in three dimensions, rotational motion, Lagrangian mechanics, small vibrations, normal modes. Introduction to Hamiltonian mechanics.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisite: PHYS 230
• Corequisite: MATH 315
• Restriction: Not open to students having passed PHYS 451 or PHYS 351

• Terms
  • Winter 2014
• Instructors
  • Gilbert P Holder

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisite: PHYS 232
• Restriction: Not open to students taking or having passed PHYS 362

• Terms
  • Winter 2014
• Instructors
  • Sabrina Leslie

Physics: 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.

Offered by: Physics

• Fall
• 3 hours lectures
• Prerequisites: CEGEP physics or PHYS 142, MATH 222
• Corequisite: MATH 314
• Restriction: Not open to students who have passed PHYS 242 or PHYS 350

• Terms
  • Fall 2013
• Instructors
  • Shaun MacDonald Lovejoy

Physics: 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.

Offered by: Physics

• Winter
• 3 hours lectures
• Prerequisites: PHYS 340 or PHYS 242, Mathematics MATH 314, MATH 315

• Terms
  • Winter 2014
• Instructors
  • Michael Hilke

Atmospheric & Oceanic Sciences: Linear theory of waves in rotating and stratified media. Geostrophic adjustment and model initialization. Wave propagation in slowly varying media. Mountain waves; waves in shear flows. Barotropic, baroclinic, symmetric, and Kelvin-Helmholtz instability. Wave-mean flow interaction. Equatorially trapped waves.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 314, MATH 315, or permission of instructor

• Terms
  • Winter 2014
• Instructors
  • David N Straub

Atmospheric & Oceanic Sciences: Review of dry and moist atmospheric thermodynamics concepts. Atmospheric aerosols, nucleation of water and ice. Formation and growth of cloud droplets and ice crystals. Initiation of precipitation. Severe storms and hail. Weather modification. Numerical cloud models.

Offered by: Atmospheric & Oceanic Sciences

• 3 hours
• Prerequisites (Undergraduates): ATOC 315, MATH 314, and MATH 315, or permission of instructor.
• Restriction: Not open to students who have taken ATOC 621.

• Terms
  • Fall 2013
• Instructors
  • Man K Yau

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Prerequisites (Undergraduates): ATOC 315, MATH 314, and MATH 315, or permission of instructor.
• Restriction: Not open to students who have taken ATOC 620.

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: Introduction to the components of the climate system. Review of paleoclimates. Physical processes and models of climate and climate change.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 3 hours lecture
• Prerequisite (Undergraduate): MATH 315, or permission of instructor

• Symbols:
• Taught only in alternate years

• Terms
  • This course is not scheduled for the 2013 academic year
• Instructors
  • There are no professors associated with this course for the 2013 academic year.

Atmospheric & Oceanic Sciences: 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.

Offered by: Atmospheric & Oceanic Sciences

• Winter
• 2 hours lecture; 2 hours laboratory
• Prerequisite (Undergraduate): ATOC 412 and ATOC 540 or permission of instructor.

• Terms
  • Winter 2014
• Instructors
  • Eyad Hashem Atallah