Note: This is the 2011–2012 edition of the eCalendar. Update the year in your browser's URL bar for the most recent version of this page, or click here to jump to the newest eCalendar.
Jump To:
- Earth and Planetary Sciences Admission Requirements and Application Procedures
- Earth and Planetary Sciences Faculty
- Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) (45 credits)
- Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) — Environment (48 credits)
- Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences
- Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences — Environment
Earth and Planetary Sciences
Location
Location
- Department of Earth and Planetary Sciences
- Frank Dawson Adams Building
- 3450 University Street
- Montreal, QC H3A 2A7
- Canada
- Telephone: 514-398-6767
- Fax: 514-398-4680
- Email: gradinquiry [at] eps.mcgill.ca
- Website:
About Earth and Planetary Sciences
About Earth and Planetary Sciences
The Department of Earth and Planetary Sciences offers both M.Sc. and Ph.D. degree programs. Graduate programs are based on research, although some courses are required to build the backgrounds of students. Research in the Department is wide-ranging. It includes studies of the geochemistry of the mantle, the nature of processes concentrating metals in hydrothermal mineral deposits, experimental studies of the controls of viscosity in magmas and the mechanisms of volcanic eruption, the fixation of mercury in marine sediments, the nature of changes in atmospheric chemistry in the early and late Precambrian, mechanisms of faulting, the evolution of topography during orogenesis, wetland hydrogeology, and planetary-scale ocean biogeochemistry and its relationship to global warming. There is a very substantial interdisciplinary basis to much of the research.
Facilities in the Department include low-temperature and pressure to high-temperature and pressure experimental laboratories, a stable-isotope mass spectrometer, XRF, laser-ablation ICP-MS, and electron microprobe, as well as atomic absorption spectrometers. Our students also make substantial use of other facilities at ³ÉÈËVRÊÓƵ and at nearby Université du Québec à Montréal.
Financial assistance is available in the form of teaching assistantships, research assistantships, and scholarships.
Areas of Research
Aquatic Geochemistry
Application of chemical thermodynamics, kinetics, and surface chemistry to the characterization of mineral-solution interactions in aquatic environments, carbonate geochemistry, early diagenesis of marine and coastal sediments, trace metal and environmental geochemistry in freshwater and marine systems.
Biomineralization
Investigation of process occurring at the interface between inorganic and organic phases leading to the nucleation and growth of crystals in both natural and synthetic systems. Pathogenic mineralization and calcification in mammalian cells and tissues. Investigating biomarkers as signatures of ancient biological activity in terrestrial and extraterrestrial materials.
Economic Geology
Studies of the genesis of hydrothermal mineral deposits through a combination of field-based, experimental, and theoretical methods. Research focuses on the understanding of physico-chemical controls of mineralization, through geological mapping of deposits, experimental studies of metal solubility and speciation in hydrothermal systems, simulations of hydrothermal alteration, and theoretical studies designed to estimate conditions of alteration and ore formation. Trace-element chemistry of minerals as quantitative probes of the compositions of ore-forming fluids.
Hydrogeology
Studies of pore-water flow in northern peatlands, heat transport, heat as a tracer of natural systems, groundwater modeling, coupled numerical models of pore water flow and heat transport with freeze/thaw processes, and the impact of melting tropical glaciers on water resources.
Igneous Petrology
Experimental studies of the structure, thermodynamics, and transport properties (diffusion and viscosity) of silicate melts and applications to igneous petrogenesis. The nature of the Earth's upper mantle and the processes within it which give rise to basaltic volcanism on both the Earth and the other terrestrial planets. Applications of laser ablation ICPMS; Petrology, geochemistry, and tectonics of the Appalachian lithosphere.
Mineralogy
Chemistry and crystallography of carbonate minerals. Experimental investigations of the effect of environmental factors (e.g., solution composition and temperature) on the morphology and composition of calcite.
Oceanic Biogeochemistry
Links between the marine ecosystem and climate through observations of the modern ocean, simulations of ocean biogeochemistry with computer models, and sedimentary records of past climate change.
Seismology
Subduction earthquake nucleation and rupture propagation processes. Physical mechanism of aseismic deformation transients, deep non-volcanic tremors, dynamic and static stress triggering of low-frequency earthquakes and transients. Pore-fluid pressure coupling with frictional strength and slip.
Tectonics
The interactions of climate and tectonics, especially in regard to the formation and degradation of orogens. Understanding the paleoclimatic and neotectonic history of Plio-Pleistocene landscape development using cosmogenic-dating techniques. Archean orogenic processes. Fluid flow in faults, granular flow in faults, and catastrophic structural/geochemical events in faults.
Isotopic Geochemistry and Sedimentary Geology
Sedimentology, stratigraphy, and isotope geochemistry as guides to reconstructing ancient environments. Reconstruction of paleoenvironmental change during the Neoproterozoic to early Phanerozoic. Relationships between tectonics (i.e. supercontinental break-up and assembly), seawater chemistry and ocean redox, severe climatic fluctuations (including snowball Earth), and the origin and diversification of animals. Recovery of the geochemical memory of large-scale Earth system processes (e.g., microbial control of the global S cycle; anthropogenic manipulation of atmospheric OH abundances). Investigations of microbial biogeochemistry under an anoxic Archean atmosphere, to constrain mass fluxes in the Phanerozoic geologic sulfur cycle, and to track processes that control the pollution-cleansing oxidants (OH, O3) in the modern atmosphere.
Volcanology
Petrology and geochemistry of intermediate and felsic magmas. Understanding physical processes and forecasting eruptions at active subduction-zone volcanoes. Geochemistry of volcanic gases, their use for eruption prediction, and their impact on the atmosphere.
Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) (45 credits) |
---|
The nature of graduate research in the Department of Earth and Planetary Sciences is highly variable. As a result, students may enter the graduate program with backgrounds in Earth sciences, chemistry, or physics, depending on their research interests and the supervisor with whom they wish to work. Students pursuing an M.Sc. are required to take four courses, but their major project is an M.Sc. thesis that typically results in a journal publication. Research for the thesis is typically begun in the first year of residence and completed, together with the written results, in the second year of residence. Students graduating from the program typically proceed to a Ph.D. or work in the mineral-exploration or petroleum industries. It is possible to ‘fast-track’ to a Ph.D. program at the end of the first year if suitable progress has been demonstrated. |
Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) — Environment (48 credits) |
---|
The graduate option in Environment provides students with an appreciation of the role of science in informing decision-making in the environment sector, and the influence that political, socio-economic, and ethical judgments have. The option also provides a forum whereby graduate students bring their disciplinary perspectives together and enrich each other's learning through structured courses, formal seminars, and informal discussions and networking. Students that have been admitted through their home department or Faculty may apply for admission to the option. Option requirements are consistent across academic units. The option is coordinated by the MSE, in partnership with participating academic units. |
Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences |
---|
The nature of graduate research in the Department of Earth and Planetary Sciences is highly variable. As a result, students may enter the graduate program with backgrounds in Earth sciences, chemistry, or physics, depending on their research interests and the supervisor with whom they wish to work. Ph.D. students typically enter with an M.Sc., in which case they are required by our regulations to take only two courses, although a supervisor may require more, depending on the suitability of the student’s background. Aside from courses, the first year is occupied by early work on the thesis project that constitutes the bulk of the Ph.D., with preparation for an oral examination on their research proposal at the end of the first year. Conduct of the research, and preparation of the results, for thesis and publication, typically takes three additional years. Students entering the Ph.D. program without an M.Sc. are required to take a full year of courses before embarking on the processes described above. Students graduating from our Ph.D. program pursue careers in universities and government-funded research institutes, and in the mineral-exploration and petroleum industries. |
Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences — Environment |
---|
The graduate option in Environment provides students with an appreciation of the role of science in informing decision-making in the environment sector, and the influence that political, socio-economic and ethical judgments have. The option also provides a forum whereby graduate students bring their disciplinary perspectives together and enrich each other's learning through structured courses, formal seminars, and informal discussions and networking. Students that have been admitted through their home department or Faculty may apply for admission to the option. Option requirements are consistent across academic units. The option is coordinated by the MSE, in partnership with participating academic units. |
Earth and Planetary Sciences Admission Requirements and Application Procedures
Earth and Planetary Sciences Admission Requirements and Application Procedures
Admission Requirements
Admission Requirements
Applicants should have an academic background equivalent to that of a ³ÉÈËVRÊÓƵ graduate in the Honours or Majors program in geology, geophysics, chemistry, or physics (3.0 out of 4.0). The admissions committee may modify the requirements in keeping with the field of graduate study proposed. In some cases, a qualifying year may be required.
Application Procedures
Application Procedures
Dates for Guaranteed Consideration
For dates for guaranteed consideration, please consult the following website: www.mcgill.ca/gradapplicants/programs. Then select the appropriate program.
Applicants who want to be considered for entrance awards, or requiring financial assistance, should apply before the dates for guaranteed consideration. There are no special forms required to apply for financial aid from the Department, as all applicants will be considered for the awards for which they are eligible.
Students should first contact potential supervisors within the Department of Earth and Planetary Sciences () and assess their interest in accepting new students before starting the formal application procedure. General inquiries concerning the Department should be addressed to Graduate ³ÉÈËVRÊÓƵ, Department of Earth and Planetary Sciences. Candidates should indicate their field(s) of interest when making formal application for admission.
³ÉÈËVRÊÓƵ’s online application form for graduate program candidates is available at www.mcgill.ca/gradapplicants/apply.
Earth and Planetary Sciences Faculty
Earth and Planetary Sciences Faculty
Chair |
---|
A. Hynes |
Emeritus Professors |
---|
Jafar Arkani-Hamed; B.Eng.(Tehran), Ph.D.(MIT) |
Wallace H. MacLean; B.Geol.Eng.(Colo. Sch. of Mines), M.Sc.(A.), Ph.D.(McG.) |
Robert F. Martin; B.Sc.(Ott.), M.S.(Penn. St.), Ph.D.(Stan.) |
Colin W. Stearn; B.Sc.(McM.), M.S., Ph.D.(Yale), F.R.S.C. |
Professors |
---|
Don Baker; B.A.(Chic.), Ph.D.(Penn. St.) |
Donald Francis; B.Sc.(McG.), M.Sc.(Br. Col.), Ph.D.(MIT) (Dawson Professor of Geology) |
Andrew J. Hynes; B.Sc.(Tor.), Ph.D.(Cant.) (William E. Logan Professor of Geology) |
Olivia G. Jensen; B.Sc., M.Sc., Ph.D.(Br. Col.) |
Alfonso Mucci; B.Sc., M.Sc.(Montr.), Ph.D.(Miami) |
John Stix; A.B.(Dart.), M.Sc., Ph.D.(Tor.) |
A.E. (Willy) Williams-Jones; B.Sc., M.Sc.(Natal), Ph.D.(Qu.) |
Associate Professors |
---|
Galen Halverson; B.A.(Mont.), M.A., Ph.D.(Harv.) (T.H. Clark Chair in Sedimentary and Petroleum Geology) |
Jeanne Paquette; B.Sc., M.Sc.(McG.), Ph.D.(Stonybrook) |
Hojatollah Vali; B.Sc., M.Sc., Ph.D.(Munich) (Director, Electron Microscopy Centre) |
Assistant Professors |
---|
Eric Galbraith; B.Sc.(McG.), Ph.D.(Br. Col.) |
Sarah Hall; B.A.(Hamilton), Ph.D.(Calif.-Santa Cruz) |
Yajing Liu; B.Sc.(Peking), Ph.D.(Harv.) |
Jeffrey McKenzie; B.Sc.(McG.), M.Sc., Ph.D.(Syrac.) |
Christie Rowe; A.B.(Smith), Ph.D.(Calif.-Santa Cruz) |
Vincent van Hinsberg; Propadeuse(Utrecht), Doctorandus(Utrecht), Ph.D.(Brist.) |
Boswell Wing; A.B.(Harv.), M.A., Ph.D.(Johns Hop.) (Canada Research Chair in Earth Systems Science (Geochemistry)) |
Faculty Lecturer |
---|
W. Minarik; B.A.(St. Olaf), M.Sc.(Wash.), Ph.D.(Rensselaer Poly.) |
Adjunct Professors |
---|
M. Duchesne, M. Riedel, H. Short, B. Sundby |
Retired Professor |
---|
R. Hesse |
Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) (45 credits)
For more information, see Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) (45 credits).
Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) — Environment (48 credits)
For more information, see Master of Science (M.Sc.); Earth and Planetary Sciences (Thesis) — Environment (48 credits).
Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences
Highly qualified B.Sc. graduates may be admitted directly to the Ph.D. 1 year. Students with the M.Sc. degree are normally admitted to the Ph.D. 2 year. Students are required to take six graduate-level courses in the Ph.D. 1 year, and two courses plus a comprehensive oral examination in the Ph.D. 2 year.
For more information, see Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences.
Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences — Environment
For more information, see Doctor of Philosophy (Ph.D.); Earth and Planetary Sciences — Environment .