Co-Director, Institute for Innovation in Imaging and Associate Professor of Radiology
Massachusetts General Hospital and Harvard Medical School
In the Chemistry department Faculty, graduate students, postdoctoral fellows, undergraduates and staff members work cooperatively in a collegial environment to tackle some of the world's most pressing problems related to energy, health and sustainability.
Research areas in the department cover a wide range of subject matter, including applied chemistry, chemical synthesis, biological chemistry, environmental chemistry, chemical analysis, materials chemistry, chemical physics and theoretical chemistry.
All students admitted into our graduate program will receive a competitive stipend. Tuition fees are paid for all qualifying PhD students, as part of complete multi-year funding packages that also include funding via Teaching Assistantships (TA) and Graduate Research Assistantships (GRA).
Outstanding facilities and resources accommodate more than 500 graduate students, postdoctoral fellows and faculty that call the Department of Chemistry home. The Department has one of the most comfortable and up-to-date research spaces in North America.
The Faculty of Graduate and Postdoctoral Studies establishes the minimum admission requirements common to all applicants, usually a minimum overall average in the B+ range (76% at UBC). The graduate program that you are applying to may have additional requirements. Please review the specific requirements for applicants with credentials from institutions in:
Each program may set higher academic minimum requirements. Please review the program website carefully to understand the program requirements. Meeting the minimum requirements does not guarantee admission as it is a competitive process.
Applicants from a university outside Canada in which English is not the primary language of instruction must provide results of an English language proficiency examination as part of their application. Tests must have been taken within the last 24 months at the time of submission of your application.
Minimum requirements for the two most common English language proficiency tests to apply to this program are listed below:
Overall score requirement: 92
Overall score requirement: 6.5
Some programs require additional test scores such as the Graduate Record Examination (GRE) or the Graduate Management Test (GMAT). The requirements for this program are:
The GRE is required by some applicants. Please check the program website.
All applicants have to submit transcripts from all past post-secondary study. Document submission requirements depend on whether your institution of study is within Canada or outside of Canada.
A minimum of three references are required for application to graduate programs at UBC. References should be requested from individuals who are prepared to provide a report on your academic ability and qualifications.
Many programs require a statement of interest, sometimes called a "statement of intent", "description of research interests" or something similar.
Students in research-based programs usually require a faculty member to function as their supervisor. Please follow the instructions provided by each program whether applicants should contact faculty members.
Permanent Residents of Canada must provide a clear photocopy of both sides of the Permanent Resident card.
All applicants must complete an online application form and pay the application fee to be considered for admission to UBC.
Applicants who are interested in the production, preparation, and application of nuclear isotopes for science and medicine may consider the IsoSiM program. Applicants who are interested in quantum materials may consider the QuEST program.
|Fees||Canadian Citizen / Permanent Resident / Refugee / Diplomat||International|
|Application Fee||No application fee||No application fee|
|Installments per year||3||3|
|Tuition per installment||$1,767.18||$3,104.64|
|Tuition per year|
(plus annual increase, usually 2%-5%)
|Int. Tuition Award (ITA) per year (if eligible)||$3,200.00 (-)|
|Other Fees and Costs|
|Student Fees (yearly)||$1,057.05 (approx.)|
|Costs of living (yearly)||starting at $17,366.20 (check cost calculator)|
Applicants to UBC have access to a variety of funding options, including merit-based (i.e. based on your academic performance) and need-based (i.e. based on your financial situation) opportunities.
All full-time students who begin a UBC-Vancouver Ph.D. program in Chemistry will receive a funding package of at least $22,000 for each of the first five years of their program (contingent on satisfactory teaching and research performance). The funding package may consist of any combination of internal or external awards, teaching-related work, research assistantships, and graduate academic assistantships. In addition to this salary, Ph.D. students receive full tuition awards paid for by funds from the Graduate Student Initiative and the Faculty of Science for the first five years of the program.
All applicants are encouraged to review the awards listing to identify potential opportunities to fund their graduate education. The database lists merit-based scholarships and awards and allows for filtering by various criteria, such as domestic vs. international or degree level.
Graduate programs may have Teaching Assistantships available for registered full-time graduate students. Full teaching assistantships involve 12 hours work per week in preparation, lecturing, or laboratory instruction although many graduate programs offer partial TA appointments at less than 12 hours per week. Teaching assistantship rates are set by collective bargaining between the University and the Teaching Assistants' Union.
Many professors are able to provide Research Assistantships (GRA) from their research grants to support full-time graduate students studying under their direction. The duties usually constitute part of the student's graduate degree requirements. A Graduate Research Assistantship is a form of financial support for a period of graduate study and is, therefore, not covered by a collective agreement. Unlike other forms of fellowship support for graduate students, the amount of a GRA is neither fixed nor subject to a university-wide formula. The stipend amounts vary widely, and are dependent on the field of study and the type of research grant from which the assistantship is being funded. Some research projects also require targeted research assistance and thus hire graduate students on an hourly basis.
Canadian and US applicants may qualify for governmental loans to finance their studies. Please review eligibility and types of loans.
All students may be able to access private sector or bank loans.
Many foreign governments provide support to their citizens in pursuing education abroad. International applicants should check the various governmental resources in their home country, such as the Department of Education, for available scholarships.
The possibility to pursue work to supplement income may depend on the demands the program has on students. It should be carefully weighed if work leads to prolonged program durations or whether work placements can be meaningfully embedded into a program.
Canadian residents with RRSP accounts may be able to use the Lifelong Learning Plan (LLP) which allows students to withdraw amounts from their registered retirement savings plan (RRSPs) to finance full-time training or education for themselves or their partner.
Please review Filing taxes in Canada on the student services website for more information.
Applicants have access to the cost calculator to develop a financial plan that takes into account various income sources and expenses.
192 students graduated between 2005 and 2013: 3 graduates are seeking employment; 5 are in non-salaried situations; for 31 we have no data (based on research conducted between Feb-May 2016). For the remaining 153 graduates:
These statistics show data for the Doctor of Philosophy in Chemistry (PhD). Data are separated for each degree program combination. You may view data for other degree options in the respective program profile.
|2013||Dr. Morrison investigated cold molecular plasmas formed from highly excited nitric oxide molecules. This exotic state of matter presents an experimentally accessible environment in which to gain further understanding of correlated plasma systems--such as those found in fusion reactors, and interstellar space.|
|2013||Dr. Musgrove conducted research in electro-chemical processes. She developed a new method for creating thin films on electrode surfaces and identified their characteristics using fluorescence and atomic-force microscopy. These discoveries may be developed for use in sensors for biological molecules or as model cell membranes.|
|2013||Dr. Sriskandakumar's research focussed on the ongoing attempts to develop promising alternatives to metallo-anticancer drugs. A new model was proposed for the activation and effectiveness of ruthenium-based anticancer drugs by probing their electronic structures. This helped to create new strategies to make effective metal-based anticancer drugs.|
|2013||Dr. Yu developed catalysts for the formation of bio-degradable and bio-compatible materials used in industrial and medical applications. She investigated the nature of these catalysts, allowing them to tune the physical properties of the resulting materials. Her work lead to a new family of functionalized polymeric materials for drug delivery systems.|
|2013||Dr. Dauth performed his research in the field of organo-metallic chemistry. He designed new and green pathways to create valuable alcohols and amines from cheap and readily available starting materials. His research lays the foundation for the future development of pharmaceuticals or materials.|
|2013||Dr. Zhu studied the chemical reactivity of oxygen atoms. He developed a general method in the laboratory to synthesize many novel organic molecules which are important in the pharmaceutical industries. His research might provide a new and reliable strategy for scientists to synthesize new, potent anti-cancer drugs in the future.|
|2013||Dr. Majewski studied the fundamental charge transfer processes that are involved in the conversion of visible light to usable energy within artificial photosynthetic assemblies. These assemblies, prepared and designed by Dr. Majewski, mimic the photosynthetic process Nature has perfected and offer insight into a form of solar energy conversion.|
|2013||Dr. Liu worked on the development of chemical separation instruments. He designed a novel device that could obtain pure targeted compound from complex mixtures. This technique could serve the needs in sample preparation for both academic and industrial activities.|
|2013||Dr. Kravchenko has performed theoretical work in the area of physical chemistry. She created computer models describing the behaviour of fluids, a fundamental problem that requires large computational power. The outcomes of this research are relevant to a wide range of research areas, from atmospheric chemistry to industrial aerosols.|
|2013||Dr. Sun completed his research on ways to make organic compounds more efficiently. His studies focussed on developing new methods to generate novel molecules that are important in the pharmaceutical and material industries. His research has the potential to benefit scientists who are developing more effective drugs.|
Chemistry covers a wide range of subject matter, from synthetic organic chemistry to chemical physics and theory, including inorganic, organic, analytical, biological, physical, theoretical, nuclear, environmental, and materials chemistry.