Basic statistical mechanics and applications to thermochemistry and kinetics; intermolecular interactions; concepts in reaction dynamics.
Advanced topics in Physical Chemistry with emphasis on biochemical systems. Spectroscopic methods for (bio) molecular structure determination, including IR, NMR, UV/VIS; colloid chemistry; polymers and bio-polymers, bonding structure and statistical mechanics; physical chemistry of membranes, active transport and diffusion; oscillatory (bio)chemical reactions.
A detailed discussion of the structure, bonding, spectroscopy and reactivity of transition metal compounds. After an overview of descriptive chemistry, the focus is on coordination and organometallic chemistry, with an introduction to catalysis and biocoordination chemistry. The laboratory focuses on intermediate and advanced inorganic syntheses, and classical and instrumental characterization methods. This laboratory is six hours in duration and occurs every week.
Principles of synthesis organic and functional group transformations; compound stereochemistry, spectroscopy and structure elucidation. This course includes a four hour laboratory every week.
The chemistry of heterocycles, nucleic acids, terpenes, steroids and other natural products; amino acids, proteins and carbohydrates; introduction to enzyme structure and catalysis.
This course includes a four hour laboratory every week.
The course focuses on the important concepts in the design and synthesis of drugs. The course may include the principles of pharmacology, drug metabolism and toxicology. Strategies for generating valuable active compounds and structure/activity relationships involved in selective transformations of available building blocks into diversely functionalized derivatives will be discussed. The course provides an overview of reactions used at different stages of the drug development process, using representative examples from the literature and case studies of drugs where applicable.
In this course students will learn about the following analytical techniques used in organic structure determination: mass spectrometry, IR spectroscopy, NMR spectroscopy, and ultraviolet-visible spectroscopy. There will be focus on a systematic approach in structure determination through various spectroscopy. Students will receive hands-on training in spectral interpretation, processing and analysis as well as training on the use of different computer software for the purpose of analysis.
Students will learn about analytical techniques used in environmental chemistry, including: gas and liquid chromatography, mass spectrometry, atomic absorption, and ultraviolet-visible spectroscopy. Environmental sampling and ecotoxicology will also be covered. Students will carry out laboratory analyses and receive hands-on training with analytical instrumentation commonly used in environmental chemistry.
Advanced topics in inorganic chemistry will be covered at a modern research level. The exact topic will be announced in the Winter Session prior to the course being offered.
This course offers an in-depth understanding of organic chemistry by systematically exploring the factors and principles that govern organic reactions. The first half of the course covers fundamentals including boding theories, kinetics, thermodynamics, transition state theory, isotope effects, and Hammett equations. In the second half, these topics are applied to the study of different types of organic reactions, such as nucleophilic substitutions, polar additions/eliminations, pericyclic reactions and radical reactions.
This course will teach biochemical reactions in the context of Organic Chemistry. This course will build on topics from CHMC47H3. Application of enzymes in organic synthesis, chemical synthesis of complex carbohydrates and proteins, enzyme catalyzed proton transfer reactions and co-enzymes will be discussed in depth with recent literature examples. Experiential learning is an integral part of this course. Students will explore the applications of Bio-Organic Chemistry in healthcare and industrial settings as part of an experiential learning project
This course introduces quantitative approaches to describe the behaviour of organic chemicals in the environment. Building upon a quantitative treatment of equilibrium partitioning and kinetically controlled transfer processes of organic compounds between gaseous, liquid and solid phases of environmental significance, students will learn how to build, use and evaluate simulation models of organic chemical fate in the environment. The course will provide hands-on experience with a variety of such models.
This course will explore the role of the chemical elements other than “the big six” (C, H, O, N, P, S) in living systems, with a focus on metal cations. The topic includes geochemistry and early life, regulation and uptake of metallic elements, structure-function relationships in metalloproteins.
Advanced topics in biological chemistry will be covered at a modern research level. The exact topic will be announced in the Winter Session prior to the course being offered.
The 'twelve principles' of green chemistry will be discussed in the context of developing new processes and reactions (or modifying old ones) to benefit society while minimizing their environmental impact. Examples will be taken from the recent literature as well as from industrial case studies.
You can find the names and contact information for the current course coordinators by visiting the Chemistry website.
This course involves participation in an original research project under the direction of a faculty supervisor. Approximately 260 hours of work are expected in CHMD90Y3. The topic will be selected in conference with the course coordinator who will provide project descriptions from potential faculty supervisors. Progress will be monitored during periodic consultations with the faculty supervisor as well as the submission of written reports. The final results of the project will be presented in a written thesis as well as an oral and/or poster presentation at the end of the term.
Please see the note below on registration in CHMD90Y3.
You can find the names and contact information for the current course coordinators by visiting the Chemistry website.
This course involves participation in an original research project under the direction of a faculty supervisor. Approximately 130 hours of work are expected in CHMD91H3. The topic will be selected in conference with the course coordinator who will provide project descriptions from potential faculty supervisors. Progress will be monitored during periodic consultations with the faculty supervisor as well as the submission of written reports. The final results of the project will be presented in a written thesis as well as an oral and/or poster presentation at the end of the term.
Please see the note below on registration in CHMD91H3.
A lab course designed to introduce students to modern synthetic methods while performing multi-step syntheses. The course will consist of two, six hour lab days every week. Students will develop advanced practical synthetic and analytic skills by working with important reactions taken from different chemistry disciplines.
A review of the major characteristics and interpretations of cities, urban processes and urban change as a foundation for the Program in City Studies. Ideas from disciplines including Anthropology, Economics, Geography, Planning, Political Science and Sociology, are examined as ways of understanding cities.
An introduction to the philosophical foundations of research, major paradigms, and methodological approaches relevant to Programs in City Studies. This course is designed to increase awareness and understanding of academic work and culture, enhance general and discipline-specific academic literacy, and create practical opportunities for skills development to equip students for academic success in City Studies.
After critically examining the history of urban planning in Canada, this course explores contemporary planning challenges and engages with planning’s ‘progressive potential’ to address social justice issues and spatialized inequality through an examination of possible planning solutions.
This course provides an overview of the history, theory, and politics of community development and social planning as an important dimension of contemporary urban development and change.
This course is the foundations course for the city governance concentration in the City Studies program, and provides an introduction to the study of urban politics with particular emphasis on different theoretical and methodological approaches to understanding urban decision-making, power, and conflict.
This course introduces quantitative and qualitative methods in city studies. Students will engage in observation and interviews; descriptive data analysis and visualization; surveys and sampling; and document analysis.
This introductory course will encourage students to exercise their relational and comparative imagination to understand how the urban issues and challenges they experience in Scarborough and Toronto are interconnected with people, ideas and resources in other parts of the world. Students will examine the complexities of urbanization processes across different regions in the world, including themes such as globalization, urban governance, sustainability, climate change, equity and inclusion. Through interactive lectures, collaborative work and reflective assignments, students will learn to apply comparative and place-based interventions for fostering inclusive, equitable, and sustainable urban futures.
An introduction to economic analysis of cities, topics include: theories of urban economic growth; the economics of land use, urban structure, and zoning; the economics of environments, transportation, and sustainability; public finance, cost-benefit analysis, the provision of municipal goods and services, and the new institutional economics.
This course engages students in a case study of some of the issues facing urban communities and neighbourhoods today. Students will develop both community-based and academic research skills by conducting research projects in co-operation with local residents and businesses, non-profit organizations, and government actors and agencies.
With a focus on building knowledge and skills in community development, civic engagement, and community action, students will ‘learn by doing’ through weekly community-based placements with community organizations in East Scarborough and participatory discussion and written reflections during class time. The course will explore topics such as community-engaged learning, social justice, equity and inclusion in communities, praxis epistemology, community development theory and practice, and community-based planning and organizing. Students will be expected to dedicate 3-4 hours per week to their placement time in addition to the weekly class time. Community-based placements will be organized and allocated by the course instructor.
This course examines how planning and housing policies help shape the housing affordability landscape in North American cities. The course will introduce students to housing concepts, housing issues, and the role planning has played in (re)producing racialized geographies and housing inequality (e.g., historical and contemporary forms of racial and exclusionary zoning). We will also explore planning’s potential to address housing affordability issues.
Constitutional authority, municipal corporations, official plans, zoning bylaws, land subdivision and consents, development control, deed restrictions and common interest developments, Ontario Municipal Board.