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The hallmark of the Life Sciences program is a unique blend of disciplines represented by basic and clinical biomedical science departments in the Faculty of Health Sciences. These departments include Biomedical and Molecular Sciences, Public Health Sciences, and Pathology and Molecular Medicine, in collaboration with the Cancer Research Institute, the Centre for Neuroscience Studies, the Cardiac, Circulation and Respiratory Group, and the Research Group in Reproduction and Development.

Biochemistry is the branch of science that explores the structures and chemical processes of molecules in living organisms that interact to form cells, tissues, and whole organisms. The Biochemistry program at Queen’s provides students with in-depth training in a wide range of important topics that are related to these processes, including the mechanisms of cancer progression, cellular communication, and the molecular and chemical basis of infection, inheritance, and disease.

A degree in Mathematical Physics provides you with training in theory, computation, and advanced mathematical modelling techniques relevant for fundamental and applied research. In particular, mathematical physicists study the numeric, combinatoric, algebraic, and computational frameworks that are used to form models of essentially anything that can be quantified. The skills obtained are highly sought after and transferrable to a wide range of fields.

Geological engineers combine core engineering fundamentals with a broad slate of geological knowledge, ranging from geology to geotechnical engineering. You will study physics, chemistry, applied mathematics, and natural processes such as earthquakes, volcanoes, plate tectonics, and mountain formation. You will also acquire field, laboratory, and computer simulation skills and training in state-of-the-art geological investigation and engineering analysis tools.

The only program of its kind in North America, Engineering Chemistry graduates are accredited as both chartered chemists and as professional engineers. Get a strong foundation in two disciplines, covering organic and inorganic chemistry, reactivity, structural determination and molecular materials and focusing on the pillars of chemical diagnostics, alternative energy, and process synthesis.

The Certificate in Disability and Physical Activity (DIPA) is offered through a collaboration between the School of Kinesiology and Health Studies and Revved Up , an adapted exercise program. The goal of the Revved Up program is to provide world-class, community-based exercise programming that fosters healthy living and quality of life among people living with mobility impairment, intellectual disability, and/or cancer.

Biomedical Engineering involves the application of engineering principles to understand, modify, or control biological systems with the objective of generating solutions to health-related problems. This area is diverse and multidisciplinary, bringing in concepts from chemistry, cell biology, mechanics, bioelectricity, mathematics, and physiology. The multidisciplinary nature of the field is reflected in our collaborative biomedical engineering Master’s and PhD programs.

Understanding the evolution of drug resistant diseases draws upon knowledge of genetics, genomics, epidemiology, and population ecology and these are all areas of study steeped in both Biology and Mathematics. This example is just one of many that could be used to highlight the growing need for quantitative literacy in academics, medicine, and industry. The Biology and Mathematics SSP incorporates courses from both departments and combines them with specialized courses in “BioMath” to provide an exceptional learning experience in this emerging field.

Engineering physics combines the practical skills of engineering with the deep knowledge of a scientist, applying analytical and lateral thinking to modern engineering challenges. Courses in quantum mechanics, laser optics and nanotechnology will help prepare you for an engineering career at the leading edge of technology. You will acquire advanced problem-solving and instrumentation skills, and will be able to apply superior mathematical, analytical and abstract-thinking ability to modern engineering challenges.