Chemical Engineering 2023
CHEM 001: Characterization of Reaction Mechanisms and Treatment Effects for the Non-Thermal Ammonia Plasma Functionalization of Multi-Walled Carbon Nanotubes; (Coulombe)
Professor Sylvain Coulombe
sylvain.coulombe [at] mcgill.ca |
Research Area
Non-Thermal Plasma, Nanomaterials, Medtec |
Description
Ever since their discovery, multi-walled carbon nanotubes (MWCNTs) have found numerous applications in different fields due to their extraordinary property pool. In most investigations, a MWCNT-based drug-eluting coating for metallic cardiovascular implants has been developed to improve the hemocompatibility of implant surfaces. MWCNTs can be grown on 316L stainless steel mesh substrates by chemical vapour deposition. Pristine MWCNTs are chemically inert and hydrophobic. For biomedical applications, it is crucial for the MWCNTs to be chemically modified in order to reduce their cytotoxicity and to increase their chemical affinity for pharmaceutical drug molecules. A popular functionalization technique for MWCNTs, which introduces polar chemical groups, such as amines, onto the sidewalls of individual tubes, is non-thermal low-pressure plasma treatment. In this project, plasma diagnostics using techniques such as optical emission spectroscopy are performed to understand the reaction mechanisms involved during ammonia plasma functionalization. Due to the nanoscopic size of MWCNTs, the plasma treatment effects are examined by Raman spectroscopy, chemical derivatization, and x-ray photoelectron spectroscopy. Preference will be given to upper-year chemical engineering undergraduate students who took CHEE 543 – Plasma Engineering in a previous semester. Tasks per student
The student will be in charge of synthesizing MWCNTs, testing different plasma functionalization protocols on MWCNTs, performing material characterization and plasma diagnostics, as well as interpreting the results. After a thorough literature review, the efforts of the student will mainly take place in laboratory spaces under the supervision of a PhD student. |
Deliverables per student
The student will report their progress on a biweekly basis. By the end of the program, the student will give a presentation summarizing their methods and findings to the Catalytic and Plasma Process Engineering lab. |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 002: McISCE - Design and Engineering of High Voltage Pulsed and Radiofrequency Power Supplies for Plasma Processing Applications; (Coulombe)
Professor Sylvain Coulombe
sylvain.coulombe [at] mcgill.ca |
Research Area
Power Electronics, Microelectronics, Plasma Sources, Control Systems, Electrical Engineering, Engineering Physics |
Description
Plasma processing is mainly applied to the materials processing and functionalization sectors such as semiconductor and automotive manufacturing. Recent developments in the studies of non-thermal and warm plasmas have enabled significant progress in expanding plasma processing to include chemical synthesis. Synthesizing chemicals and alternative fuels with plasma processes can allow green and renewable chemical processes that can help reduce the emissions of the current carbon intensive chemical industry. Developing an effective plasma chemical synthesis process requires the integration of optimized reactor design, catalyst design and efficient power delivery. By attempting to ‘power’ chemical processes with electricity, the choice of method of delivering power is critical to create ideal plasma chemical conditions for a given synthesis reaction. Ideally a process would be exposed to many different forms of power delivery such as 60Hz AC, high voltage DC, high frequency AC (kHz region) and radiofrequency. However, constraints relating to cost of power supplies and incompatibilities between electrical systems and plasma systems begin to arise. Designing and building in-house power supplies allows the testing of different power delivery mechanisms as each one can be scaled down and modified to suit the plasma process being studied. Preforming this effectively requires electrical design knowledge that spans the engineering process from circuit schematics and simulations to manufacturing and diagnostics. Tasks per student
The student will be responsible for the design and manufacturing of power supplies and microelectronic circuits for the control of certain power supplies. Regarding the design process, the student must have a basic power electronics understanding and be familiar with circuit simulation and PCB design software. As for manufacturing and diagnostics, the student must have experience with soldering and electrical diagnostic equipment. |
Deliverables per student
The intern will report their progress on a regular basis and will work closely with supervising graduate student. By the end of the summer, the intern should have a designed power supply that can be tested on a plasma system as well as document summarizing their design, manufacturing, and diagnostic methods utilized during the duration of the project. |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 003: Creation of tunable phage-based biomaterial composites; (Dorval Courchesne)
Professor Noémie-Manuelle Dorval Courchesne
noemie.dorvalcourchesne [at] mcgill.ca |
Research Area
Sustainable biomaterials |
Description
M13 bacteriophage is used in multiple biomaterials because of its scalability and ease of production in Escherichia coli bacteria, high tolerance to mutation, and ability to assemble non-covalently into ordered structures and wires due to its high aspect ratio of around 200:1. To improve their mechanical robustness and processability into different materials (hydrogel, fibers, dry films), the phage can be blended with other polymers, such as natural protein biopolymers with excellent processability but poor genetic tunability. This project aims at optimizing a phage-biopolymer composite for material processing, and characterizing the processed fibers and films by their mechanical properties, as well as other properties endowed by genetic engineering of the phage (fluorescence, conductivity, etc.). Finding processable materials with tunable functions from purely biological sources helps advance the field of green plastic alternatives. Tasks per student
The student will be involved in all steps of the fabrication process of the composites: from the production and purification of the phage, to the composite fabrication and characterization. |
Deliverables per student
A short presentation at the end of the summer. A final report including all relevant methods, literature review and results. |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 004: Plasma Liquid Synthesis; (Girard-Lauriault)
Professor Pierre-Luc Girard-Lauriault
pierre-luc.girard-lauriault [at] mcgill.ca |
Research Area
Plasma Science and Engineering |
Description
Cold reactive plasmas (ionized gases produced by an electrical discharge) have been used in several applications, including lighting and thin film deposition. A currently innovative field of research is plasma interactions with liquids for decomposition, synthesis, or generation of active species. A particularly novel direction is the use of plasmas in interaction with organic liquids to perform the synthesis of useful small organic molecules. The project will involve the investigations of a methodology for the preparation of plasma treated organic liquids and the characterization of the species produced. The candidate should demonstrate scientific curiosity as well as maturity and autonomy. Tasks per student
- Contribution the design and assembly of a plasma liquid treatment system. - Characterization of the species produced. - Literature search. |
Deliverables per student
Set of treatment conditions maximizing the production of different species. |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 005: Advanced Characterization of Gradient Plasma Deposited Thin Organic Coatings; (Girard-Lauriault)
Professor Pierre-Luc Girard-Lauriault
pierre-luc.girard-lauriault [at] mcgill.ca |
Research Area
Plasma Science and Engineering |
Description
Synthetic Polymers are used in several technological applications due to their many desirable properties: low cost, good mechanical properties, resistance to corrosion and durability. However, their surfaces are typically hydrophobic which limits their wettability and biocompatibility. This issue can be addressed using surface engineering: selectively tailoring the surface properties of materials without affecting the desirable bulk properties. Cold reactive plasmas (ionized gases produced by an electrical discharge) have been used to alter a surface by the addition of functional groups or a functional layer. The project will involve the preparation of plasma deposited organic coatings with compositional gradients and their surface chemical characterization. This method has been demonstrated as promising to improve the performance of thin films for biomedical applications. The project will involve the use of a new X-Ray Photoelectron Spectrometer to understand the chemical composition of these coatings. Tasks per student
- Deposition of thin organic coatings using plasma technology. - Surface analysis and characterization of the deposits - Literature search |
Deliverables per student
Plasma deposited set of samples and their characterization |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 006: Advanced virucidal coatings based on calcium hydroxide microcapsules; (Girard-Lauriault)
Professor Pierre-Luc Girard-Lauriault
pierre-luc.girard-lauriault [at] mcgill.ca |
Research Area
Surface Science and Engineering |
Description
Transmission of pathogens through contaminated surfaces is one of the many important contributors to the spread of some microorganisms as they are able to survive on surfaces for relatively long time. There is therefore an established need for materials that can inhibit the transmission of infections via surfaces. In this project, you will contribute to the development of a porous microcapsule virucidal agent based on calcium hydroxide, which serves as a component to obtain highly durable multifunctional coatings which are able to target different pathogenic microorganisms via multiple active synergistic mechanism. The coatings will be evaluated for efficacy and durability. The virucidal, antibacterial and accelerated aging properties will be tested. A special focus will be put on the in-depth surface analysis of the coatings using a novel X-Ray Photoelectron Spectrometer. Tasks per student
- Preparation of thin coatings. - Surface analysis and characterization of the coatings - Literature search. |
Deliverables per student
Coated set of samples and their characterization. |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 007: Electrokinetic transport in microgel doped polyelectrolyte hydrogels.; (Hill)
Professor Reghan Hill
reghan.hill [at] mcgill.ca |
Research Area
Soft matter, nano-materials for sustainability and biotechnology. |
Description
Cavities spanning the nanometer to micron scales have been suggested to significantly enhance the conductivity of hydrogels: an important characteristic for biological and technological applications of hydrogels, including materials for batteries, energy storage devices, sensors, implants, brain tissue. The mechanism for this enhancement is unknown, but some hypotheses have been proposed, drawing on electrokinetic transport. This project seeks to experimentally test the theory, by conducting a systematic experimental study on polyelectrolyte hydrogels that are doped with uncharged microgel inclusions. Tasks per student
The student will conduct an experimental design and execute it to synthesize a series of micro-gel doped polyelectrolyte hydrogels, systematically varying the charge density of the continuous phase and the concentration of the uncharged dispersed phase. These soft nanocomposites will be characterized by measuring how their ionic conductivity varies with the micro-gel loading and polyelectrolyte charge density. |
Deliverables per student
Synthesize nanocomposites, measure their conductivity, and report the findings and methods, possibly comparing the measurements with theoretical calculations of the conductivity increment, as set out in the recent article by Hill (Ionic conductivity and hydrodynamic permeability of inhomogeneous (cavity doped) polyelectrolyte hydrogels, J. Fluid Mech., 2022) |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 008: Endothelial progenitor cell adhesion and growth on functionalized microcarriers that can be used for scale-up in bioreactors; (Hoesli)
Professor Corinne Hoesli
corinne.hoesli [at] mcgill.ca |
Research Area
Bioengineering and Molecular Biology |
Description
Despite their contribution to the advancement of modern medicine, cell therapies to treat cancer or cardiovascular diseases remain limited by the complexity of their biomanufacturing process and the high associated costs. In recent years, tools such as microscopic beads and microcarriers have been developed and used in cell therapy manufacture for the isolation, activation and expansion of cells without fully addressing the current challenges. Our team has developed a technology that allows the specific selection of cells from a mixture and the activation of those cells through contact with specific biomolecules. This bifunctionalization method combines two steps of conventional cell culture processes reducing manipulations and complexity, with the potential of greater yields for scale-up. The overall goal of this project is to assist the development of a commercial prototype using our technology for the capture and expansion of endothelial colony forming cells (ECFCs), a highly proliferative cell subtype with vascular healing potential. The specific aims of this project are to (1) determine optimal conditions for ECFC culture on bifunctionalized microcarrier and (2) establish standard operating procedures for the characterization of the cell responses to bifunctionalized microcarrier surfaces such as cell viability, cell proliferation and changes in cell phenotype. Commercialization of this technology has the potential to make cellular therapies more affordable and accessible for the treatment of a wide range of degenerative diseases. Note: This project will be conducted in collaboration with Capcyte Biotherapeutics Inc., a 山ǿ spin-off that is commercializing this technology. Please submit your application in a single pdf (cover letter, CV, transcript) directly on our website (). Under “title of position” please indicate SURE 2023: Cell responses to bifunctionalized microcarrier surface. Tasks per student
The trainee will be involved in experiment design, data acquisition, and data analysis. Wet lab techniques could include mammalian cell culture, fluorescence microscopy, flow cytometry, qPCR, Western blotting, immunocytochemistry, and more. The trainee will also be expected to present updates at group meetings. The trainee will also have the opportunity to participate in the business development activities related to the project. |
Deliverables per student
Standard operating procedure for optimized cell culture conditions and the characterization of the cell responses to bifunctionalized microcarriers. |
Number of positions
2 Academic Level
No preference Location of project
in-person |
CHEM 009: Studying endothelial differentiation dynamics with a stem cell-derived endothelial eNOS reporter; (Hoesli)
Professor Corinne Hoesli
corinne.hoesli [at] mcgill.ca |
Research Area
Bioengineering and stem cell culture |
Description
The potential of endothelial colony forming cells (ECFCs) for tissue engineering and cell therapy is increasingly evident. These highly proliferative cells can be applied to sites of ischemia and vascular damage to aid in the healing process. Upon maturation, the endothelial cells (ECs) contribute significantly to the maintenance of vessel homeostasis by producing factors such as nitric oxide, formed through the activity of endothelial nitric oxide synthase (eNOS). Nitric oxide regulates smooth muscle proliferation, vessel tone, and has anti-inflammatory properties. The maturation of proliferative ECFCs into eNOS-producing ECs is critical in vascular homeostasis but not well understood. These two cell types are nearly indistinguishable based on surface marker expression and proliferation and clonogenicity assays are laborious and time-consuming. Current eNOS reporters are either in mouse models (which lack circulating ECFCs) or they contain a promoter/reporter design, which reportedly lacks endothelial specificity due to the complex DNA methylation patterns of the native eNOS promoter. We propose to create a human pluripotent stem cell (hPSC) eNOS reporter cell line by targeted insertion of green fluorescent protein (GFP) downstream of the native eNOS coding sequence, including a cleavage peptide sequence. This will transcriptionally link the expression of GFP to native eNOS, while minimally affecting the protein functionality. We hypothesize that this reporter can be used to study the differentiation of ECFCs to EC non-invasively in real-time and will be invaluable for engineering new treatments for cardiovascular disease . Tasks per student
The trainee will be involved in experiment design, data acquisition, and data analysis. Wet lab techniques could include mammalian cell culture, fluorescence microscopy, flow cytometry, qPCR, Western blotting, immunocytochemistry, and more. The trainee will also be expected to present updates at group meetings. |
Deliverables per student
Genetic constructs for reporter cell line engineering and optimized stem cell differentiation protocols |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 010: Understanding the interplay of electronic and thermal transport in pump-probe spectroscopy experiments; (Huberman)
Professor Samuel Huberman
samuel.huberman [at] mcgill.ca |
Research Area
Nanoscale thermal and electrical transport |
Description
Pump-probe spectroscopy has become a popular technique for studying energy transport at small length and timescales. Accurate numerical modelling of these experiments remains a challenge due to the large number of input parameters required and the complicated interactions between different degrees of freedom. In this project, we will build upon our in-house software to numerically solve a set coupled heat and carrier diffusion equations for different experimental geometries. By systematically varying the different input parameters to the solver, the relative sensitivities to the quantities of interests (i.e., thermal conductivity and/or recombination time) will obtained. The predictions from these simulations will then be used to interpret recent frequency domain thermoreflectance experiments on germanium. Tasks per student
-Learn the basics of thermal and electronic transport -Read the source code of the in-house numerical solver (Matlab/Python) -Use the solver to simulate an experimental geometry (i.e., frequency domain thermoreflectance) -Predict the sensitivity of the experiment to different model parameters -Use the solver to fit to real experimental data |
Deliverables per student
A report presenting the results of the numerical calculations to be used by experimentalists |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 011: Ice rain on moving engineering surfaces; (Kietzig)
Professor Anne-Marie Kietzig
anne.kietzig [at] mcgill.ca |
Research Area
Surface Engineering |
Description
Rain drops freezing onto engineering infrastructure like wind turbines, airplanes, power transmission lines, wind shields, etc. poses a safety hazard, which has triggered considerable research activity. Traditionally, icing has been addressed by unsustainable and energy extensive heating and chemical freezing point depressants. The ultimate goal of our research program is to develop passively water and ice-shedding surfaces. This project aims at the integration of two existing experimental setups to holistically study the impact dynamics of supercooled water droplets or small ice particles onto fast moving surfaces in cold environments. Tasks per student
The physical integration of the Cold Drop Impact Apparatus (c-DIA) and the droplet levitator will require redesigning fixtures and holds. Furthermore, the student will analyze, rewrite and adapt existing Arduino codes with clear documentation to synchronize drop dispense, sample motion and filming of impact events. Finally, calibration experiments will be executed at ambient and subzero temperatures. The interested student should have experience, skills and interest in Arduino coding and debugging and very good manual skills. |
Deliverables per student
relevant safety trainings, experimental plans to carry out research tasks, weekly research reports, presentation of research results at group meetings |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 012: McISCE / Catalyst development for (1) CO2 capture and conversion to RNG; (2) Methane and Methanol upgrading to Ethylene"; (Kopyscinski)
Professor Jan Kopyscinski
jan.kopyscinski [at] mcgill.ca |
Research Area
Catalysis and reaction engineering. |
Description
Catalytic and Plasma Process Engineering (CPPE) laboratory is engaged in the development and understanding of catalyzed processes and reactor engineering concepts dedicated to sustainable energy conversion technologies. Within this project, the student in collaboration with a PhD student will focus on the synthesis of novel catalysts for (1) CO2 capture and subsequent hydrogenation to renewable natural gas and (2) the direct non-oxidative methanol conversion to value-added chemicals (olefine). The UG student will work closely together with PhD student and develop, synthesize, characterize new catalysts as well as to test them in our catalytic reactors. Tasks per student
1. Literature review 2. Catalyst preparation (impregnation, solvothem method, ...) 3. Catalyst characterization (BET, chemisorption, TPR, TPD,...) 4. Catalyst activity measurements (Fixed bed reactor, TGA, Plate Reactor connected to mass spectrometer or gas chromatograph) 5. Data analysis and kinetic modeling (material balance calculation in Excel and potentially modeling with Athena Visual Studio) |
Deliverables per student
Biweekly progress updates during group meetings. Final report and presentation. |
Number of positions
2 Academic Level
Year 3 Location of project
in-person |
CHEM 013: Blending and copolymerization of methacrylic itaconate esters; (Maric)
Professor Milan Maric
milan.maric [at] mcgill.ca |
Research Area
Polymers. |
Description
Itaconic acid (IA) has been cited as one of the top 12 platform chemicals for future bio refineries. IA has been converted to various esters and polymerized via conventional and reversible deactivation radical polymerization (RDRP), the latter providing greater control of the molecular weight distribution and the ability to access controlled microstructures. However, the molecular weights attained have been limited and we have functionalized the IA with a single methacrylic group, which should make polymerization easier, allowing higher molecular weights to be attainable and improved mechanical properties for many applications. Our group has successfully designed a diheptylitaconyl methacrylate (DHIAMA) through multi-step esterification and borylation chemistries and demonstrated its RDRP, yielding a completely new, low glass transition temperature (Tg) polymer (poly(DHIAMA)). To further examine the possibilities with this new monomer, the undergraduate student will further expand the design space by blending or by copolymerization with more rigid monomers that are largely bio-based, such as poly(isobornyl methacrylate) (poly(IBOMA)), which is a high Tg polymer. The student will learn how to apply polymer blending of the poly(DHIAMA) with other bio-based or biodegradable polymers or to copolymerize DHIAMA with other monomers to evaluate its utility in bio-based copolymer compositions. Tasks per student
The undergraduate student will be contributing towards developing a novel bio-based rubbery methacrylic functional monomer derived from itaconic acid (IA), cited as one of the top 12 platform chemicals for future biorefineries. Miscibility studies by blending the two polymers will be conducted to examine the properties of desirable blends with bio-based and or biodegradable polymers, and compatibilization schemes will be developed if necessary. The student will initially learn and apply group contribution theory to estimate miscibility a priori. Further, simple binary copolymerization of IBOMA with DHIAMA to yield statistical copolymers will also be performed by the student and copolymerization models will be tested to determine reactivity ratios and predict final copolymer microstructure and recommend compositions for targeted mechanical properties. Tensile and impact strength will be also performed near the conclusion of the project. The student will learn synthetic techniques, apply characterization tools and report the mechanical properties of various compositions. |
Deliverables per student
The student will provide methodologies to produce novel itaconate-based blends and copolymers and provide protocols for achieving desirable mechanical/physical properties with these materials. |
Number of positions
1 Academic Level
Year 3 Location of project
in-person |
CHEM 014: Microengineered organs-on-a-chip; (Moraes)
Professor Christopher Moraes
chris.moraes [at] mcgill.ca |
Research Area
Biomedical / Materials |
Description
Engineering microscale versions of tissues allows us to create designer replacement organs, understand the principles that underlie biological development, and create new sustainable approaches to healthcare and material synthesis. Here, we will investigate the use of laser machining, designer biomaterials, and microfluidic systems, to construct next-generation "organ-on-a-chip" models. Projects will primarily target pancreatic tissue engineering, breast cancer biology and brain tissue engineering; and will require the student to become familiar with cell culture, microscopy, and cleanroom fabrication. These projects broadly require an interdisciplinary mindset, a willingness to figure out how things work, and an interest in collaborating between engineers, scientists, and clinicians. Tasks per student
Hands-on training and experiments for cleanroom microfabrication, materials characterization, cell culture, and microscopy. Literature reading and scientific writing is essential. Room to explore computational modelling if that is of interest. |
Deliverables per student
Regular meetings and updates throughout the summer with prof. and grad student mentors; Short data presentations for research subgroups; one formal presentation at the end of the summer; lab notebook; project report or journal publication depending on progress made. |
Number of positions
3 Academic Level
Year 2 Location of project
in-person |
CHEM 015: DFT computations in electrocatalysis; (Seifitokaldani)
Professor Ali Seifitokaldani
ali.seifitokaldani [at] mcgill.ca |
Research Area
Electrocatalytic properties of materials; Chemical reaction mechanism; Computational materials sciences; Quantum mechanics computations; Density functional theory computations. |
Description
In this project students will learn how to run DFT computations on simple molecular system and find their optimized structures. Then, they will utilize these skills and knowledge to understand the reaction mechanism on catalytic systems, specifically for CO2 conversion and biomass upgrading. Tasks per student
Students should participate in weekly group meetings. Follow the training instruction week by week, and report their progress during the meetings. Their specific tasks include: working on Compute Canada clusters working with editors such as Vim working with CP2K code working with ASE code working with visualization softwares such as VESTA |
Deliverables per student
1. optimized simple molecular structures (e.g., CO2, CO, CH4, H2O, etc.) 2. optimizing a catalytic surface such as Cu(100) 3. calculating the adsorption energy of simple molecules on the surface, e.g., CO adsorption on Cu(100) 4. calculating the reaction energy diagram for the CO2 reduction to CH4 |
Number of positions
1 Academic Level
No preference Location of project
hybrid remote/in-person - a) students must have a Canadian bank account and b) all students must participate in in-person poster session. |
CHEM 016: Determining Crystal Properties using Density functional Theory; (Servio)
Professor Phillip Servio
phillip.servio [at] mcgill.ca |
Research Area
Energy |
Description
Humanity's increasing energy requirements, and instability in countries where most of our global oil resides, forces us to explore new/alternative methods to sustain our current quality of life. An ice-like material called gas hydrates are a possible solution to this crisis. Gas hydrates are non-stoichiometric crystalline compounds that belong to the inclusion group known as clathrates. When water molecules form a network through hydrogen bonding, they leave cavities that can be occupied by a single gas or volatile liquid. The presence of a gas or volatile liquid inside the water network thermodynamically stabilizes the structure through physical bonding via weak van der Waals forces. At present, hydrate research is recognized as an important field due to the hazards and possibilities that gas hydrates pose. Naturally occurring hydrates, containing mostly methane, exist in vast quantities within and below the permafrost zone and in sub-sea sediments. At present the amount of organic carbon entrapped in hydrate exceeds all other reserves (fossil fuels, soil, peat, and living organisms). In 2008, a panel of experts was assembled to assess the potential of gas hydrates as a future energy source in Canada. They concluded that Canada has some of the world’s most favourable conditions for the occurrence of gas hydrate, and is well positioned to be a global leader in exploration, research and development and ultimately, the exploitation of gas hydrates. Moreover, the demand for natural gas has been continuously increasing due to its relatively low emission of CO2 during combustion as well as its use as a feedstock for catalytic processes such as steam-methane reforming for the production of hydrogen. The proposed research program will employ density functional theory modeling methods on clathrates to predict crystal properties and behavior. This is essential in order to design safe, economical, and environmentally acceptable processes and facilities to exploit in-situ methane hydrate as a future energy resource. The work will focus on 3 main hydrate crystal structures (SI, SII & SH) and will also investigate the effect of several inclusion compounds (methane, carbon dioxide, propane, hydrogen, etc.) as well as their mixtures. Tasks per student
The student should have a strong background in multi-phase thermodynamics and crystallization processes. He/she should be fluent in programming and will learn how to use SIESTA. He/she will work closely with a graduate student on this project but must also be able to work independently and diligently. |
Deliverables per student
Collection and analysis of computational data for submission to his or her supervisor. The student may contribute to the writing of portions of a manuscript that may result in a publication. |
Number of positions
1 Academic Level
Year 2 Location of project
in-person |
CHEM 017: Crystallization in Acoustically-Levitated Solutions; (Servio)
Professor Phillip Servio
phillip.servio [at] mcgill.ca |
Research Area
Energy and Material Science |
Description
Primary nucleation in supercooled water droplets is classified as either homogeneous or heterogeneous. Homogeneous nucleation occurs when nuclei of the solid ice phase develop uniformly within the liquid parent phase. Heterogeneous nucleation occurs when nuclei preferentially form at structural inhomogeneities, in other words surfaces and interfaces. At the same temperature, heterogeneous nucleation occurs more favourably, which makes homogeneous nucleation and crystallization difficult to characterize. However, the study of homogeneous nucleation is critical to understanding atmospheric chemistry and crystallization phenomena. Therefore, several droplet levitation methods have been developed to eliminate the effects caused by the presence of solid surfaces and container walls. Recently, an acoustic levitation device called the TinyLev was developed. It uses two arrays of small acoustic transducers to keep several droplets stably suspended in the air simultaneously, and, therefore, eliminates the presence of solid surface effects. There has already been significant study of levitated pure water samples. However, to further our understanding of crystallization in other useful and distinctive solutions, studies of levitated nanofluids and hydrate-forming mixtures must now be conducted. Tasks per student
The student should have a strong background in multi-phase thermodynamics and crystallization processes. They will design and carry out experiments related to nucleation and freezing in acoustically-levitated solutions. Thermal and digital imaging will be used to determine both temperature and morphological characteristics. The effect of various factors, such as position, nanoparticle addition, and promoter concentration, that influence nucleation time of a sample will be investigated. They will work closely with a graduate student on this project but must also be able to work independently and diligently. |
Deliverables per student
Collection and analysis of experimental data for submission to their supervisor. The student may contribute to the writing of portions of a manuscript that may result in a publication. |
Number of positions
1 Academic Level
Year 2 Location of project
in-person |
CHEM 018: Impacts of plastic pollution in aquatic environments; (Tufenkji)
Professor Nathalie Tufenkji
nathalie.tufenkji [at] mcgill.ca |
Research Area
Water pollution |
Description
The growing presence of micro/nanoplastics in the environment has garnered significant attention from the media and the scientific community due to concerns over their potential environmental and health impacts. Upon their release to the environment, plastics degrade into smaller particles that can bioaccumulate. Detecting and visualizing these plastic particles remain a challenge due to their small size and the complex nature of environmental samples (e.g., natural waters, soils). However, the improvements in technology serve as a springboard to advance our ability to image and identify these plastic pollutants. The primary objective of this project is to develop methods to visualize and characterize different types of plastics as well as their uptake in small aquatic organisms. Tasks per student
The student will be trained in a range of nanotechnology and laboratory techniques that will include, for example: generation of micro/nanoplastics through simulated weathering conditions, particle size determination by dynamic light scattering, particle labelling techniques, fluorescence spectroscopy and advanced microscopy techniques. After receiving the required training in the lab (first month), the student will start working more independently. The student will be introduced to a range of new areas including microscopy, spectroscopy, chemistry, and environmental nanotechnology. |
Deliverables per student
A written report containing all relevant methods and results, as well as a brief literature review will be submitted. Additionally, the student will give a brief presentation to the lab group summarizing their work at the conclusion of the project. |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 019: Removal of emerging contaminants in water treatment; (Tufenkji)
Professor Nathalie Tufenkji
nathalie.tufenkji [at] mcgill.ca |
Research Area
Water treatment |
Description
Wastewaters are important stressors for aquatic ecosystems. Some (emerging) contaminants such as microplastics are refractory to conventional treatment such as coagulation, settling and filtration. New low-cost, sustainable, and functionalized materials are promising alternatives to conventional chemicals (coagulant and flocculant) used in the water treatment industry. Tasks per student
Two students will work on distinct but complementary projects. They will be trained in a range of analytical/laboratory techniques related to the water treatment industry that will include, for example: jar test procedures, raw and treated water characterization, floc size measurement, fiber enumeration, microplastics detection, etc. After receiving the required training in the lab, the students will start working more independently. The students will be introduced to a range of new areas including colloid chemistry, water chemistry, materials science, and environmental nanotechnology. |
Deliverables per student
A written report containing all relevant methods and results, as well as a brief literature review will be submitted. Additionally, the student will give a brief presentation to the lab group summarizing their work at the conclusion of the project. |
Number of positions
2 Academic Level
No preference Location of project
in-person |
CHEM 020: Developing traceable nanoplastics for environmental research; (Tufenkji)
Professor Nathalie Tufenkji
nathalie.tufenkji [at] mcgill.ca |
Research Area
Plastic pollution |
Description
During the last century, plastic drastically accumulated in the environment. Once in the environment, although plastic is a durable material, its weathering produces plastics fragments down to nanometric scale called nanoplastic. Nanoplastics are a great concern as their small size and surface properties enhance their mobility, and their interaction with organisms and pollutants. While nanoplastics are considered as ubiquitous in the environment, little is known concerning their fate and toxicity. This is principally due to the difficulties in detecting, isolating and studying nanoplastics. Due to methodological limitation, fluorescent labeled polymerized nanospheres are commonly used as model nanoplastics for fate and behavior studies. However, these particles are not representative of environmental nanoplastic. The main objective of this study is to produce a relevant traceable model nanoplastic. Tasks per student
The student will be involved in the synthesis of model traceable nanoplastics as well as the physico-chemical characterization of the produced nanoparticles (e.g., microscopy, surface charge). During the training, the student will also be introduced to new scientific areas such as environmental and colloid science; achieving a better understanding of how plastic pollution is studied. After the training completed (first month), the student will conduct the research under the supervision of a postdoctoral fellow. |
Deliverables per student
The methods, scientific references and results will be summarized in a report written by the student. Moreover, the student will present to the lab group the research accomplished and the main results. |
Number of positions
1 Academic Level
No preference Location of project
in-person |
CHEM 021: Investigating the presence of pesticides in agriculture-adjacent streams using new sampling strategies; (Yargeau)
Professor Viviane Yargeau
viviane.yargeau [at] mcgill.ca |
Research Area
Water resources protection & optimized sampling strategies |
Description
The use of pesticides is accompanied by significant risk. Unlike many other chemical pollutants, pesticides are developed with inherent biological toxicity and are intentionally released into the environment. While agrochemicals would ideally only impact the target species, pesticide from cultivated lands are transported into surrounding water systems. Consequently, the omnipresence of pesticide residues in the environment has been recognized to threaten freshwater ecosystems globally. This project aims to address these risks with the testing of a new sampling methodologies that was developed in our lab in 2022. Field samples will be collected using this new sampling strategy and will be analyzed for various contaminants including pesticides. Tasks per student
The student will first get familiarized with the background information as well as the context of the project, then will be trained on the various sample collection, preparation and analysis methods relevant to the project, which will later be applied to the samples collected. The student will work in close collaboration with the team members to develop and execute the fieldwork. The student will also participate in weekly research meetings and on a regular basis exchange with members of the other research groups involved in the project. |
Deliverables per student
A report and presentation summarizing the results obtained. |
Number of positions
1 Academic Level
No preference Location of project
in-person |