The Honours Thesis research projects listed below are available only听to 黑料不打烊 Mechanical Engineering Undergraduate students in the Honours program and registered听for听MECH 403-404 courses.
If you are interested in one of the thesis projects, please send an expression of interest to the contact email provided. Although we do our best to keep this list up-to-date, some projects may no longer be available.
If you are a professor who would like to add or remove a thesis project, please complete the honours project posting form.听
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Projects for Winter 2026 and 2026-2027 school year:
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Thesis Project 2025-1
Title: Prevent insect bites as a mechanical engineer
Supervisor: Prof. Changhong Cao
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: If you check CDC's website for guidance on prevention of mosquito bites, you will not find information more than what it was thirty years ago or even more. In the era when we are talking about sending human to Mars, we still suffer from the century-old problem of insect stinging with very little effective measures. Rolling down your sleeves, apply DEET-containing sprays when you are outside (harmful to children), stay away from water,etc. These are pretty much what we have. Millions of people died die to mosquito transmitted diseases. We need to change this! How? As a mechanical engineer? If you are interested and want to devote yourself to solving a piece of this puzzle, talk to me.
Contact e-mail: changhong.cao [at] mcgill.ca
Posted: September 5, 2024
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Thesis Project 2025-2
Title: Soft robotics metamaterials
Supervisor: Prof. Damiano Pasini
The term(s) to begin:听Winter 2026, Fall 2026, Winter 2026
Brief description: Mechanical metamaterials are manmade materials,
usually fashioned from repeating units making up a distinct architecture, such as kirigami and origami. They are engineered to achieve extreme mechanical properties, often beyond those found in most natural
materials, capable of shape shifting, sensing and actuation. In this project, the student will use the lens of mechanics of materials to generate novel soft robotics materials for target applications.
Additive manufacturing techniques will be employed to fabricate prototypes and their performance will be examined through mechanical testing.
Contact e-mail: damiano.pasini [at] mcgill.ca
Updated: September 3, 2024
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Thesis Project 2025-3
Title: Nonlinear dynamics/vibrations of architected materials for
aerospace applications
Supervisor: Prof. Damiano Pasini听
The term(s) to begin:听Winter 2026, Fall 2026, Winter 2026
Brief description: When launched in space, satellites need to endure an explosive upright boost
that generates extremely large vibrations throughout their bodies.
If uncontrolled, these vibrations end up spoiling the performance of their
components with the risk of making them nonfunctional.
In this project we study the nonlinear vibrations of a satellite component
made of ultralight weight architected materials of unprecedented performance.
The goal is to model its dynamic behaviour and understand the geometric
factors that control its highly nonlinear response at the onset of a launch
in space. The work involves a combination of theoretical and computational analysis.
Contact e-mail: damiano.pasini [at] mcgill.ca
Updated: May 9, 2023
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Thesis Project 2025-4
Title: Development of a method for recycling fibreglass composite
wind turbines
Supervisor: Prof. Larry Lessard
The term(s) to begin:听Winter 2026, Fall 2026, Winter 2026
Brief description: There is growing concern about recycling of end-of-life composite materials.
Waste fiber and other materials cannot be put into landfills so recycling
methods must be developed. Used wind turbine blades can be recycled to
recover the fibers and these fibers can be re-used to make materials for 3D
printing. So this project aims to solve two simultaneous problems: that of
growing amounts of waste and the need for stronger/more high tech materials
for the growing 3D printing industry. The project involves experimental manufacturing based on composite materials
theory.
Contact e-mail: larry.lessard [at] mcgill.ca
Updated: May 2, 2023
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Thesis Project 2025-5
Title:听MicroLED panel repair
Supervisor: Prof. Changhong Cao
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description:听Micro鈥搇ight-emitting diode (microLED) technology is widely recognized as a next鈥慻eneration display platform, offering superior brightness, extended operational lifetime, and higher energy efficiency compared to liquid crystal and organic LED technologies. Potential applications span across augmented and virtual reality systems, wearable electronics, smartphones, automotive displays, large鈥慳rea televisions, and advanced visualization walls. The student will evaluate the bond strength of solders on microLED panels to assist in the development of a microLED panel repair system.
Contact e-mail: changhong.cao [at] mcgill.ca
Posted: September 3, 2025
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Thesis Project 2025-6
Title: Review of transfer printing technologies readiness level for industrial adoption
Supervisor: Prof. Changhong Cao
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: 听Micro-Light Emitting Diodes (Micro-LEDs) have received great attention from both academia and industry in the field of display. They are found to have many advantages such as high brightness, contrast, rapid response speed, and extended operational lifetime, which fulfill the requirements of a next-generation smart monitor. However, despite those merits, several practical challenges need to be addressed before they could be deployed in mass scale. The student will delve into the literature to assess the technology readiness levels of various transfer printing technologies, ultimately writing a review paper on this topic.
Contact e-mail: changhong.cao [at] mcgill.ca
Posted: September 3, 2025
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Thesis Project 2025-7
Title: Predicting cerebral palsy gait for the design of an assistive device
Supervisor: Prof.听Guillaume Durandau
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description:听Cerebral palsy is prevalent in between 1.8 to 2.5 per 1000 children in Canada.
One of the main debilitating conditions associated with cerebral palsy is equinus gait, also known as toe walking, which
is caused by muscle spasticity that reduces the stretching capacity of the muscle-
tendon. This project proposes the creation听of a neuromusculoskeletal model reproducing cerebral
palsy muscle condition and a new AI-based controller for the simulation of
equinus gait. The project will be based on
Contact e-mail:听guillaume.durandau [at] mcgill.ca
Posted: September 8, 2025
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Thesis Project 2025-8
Title:听AI-based neuromuscular control for manual wheelchair propulsion
Supervisor: Prof. Guillaume Durandau
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: Active people in manual wheelchairs are subject to significant secondary problems: a high prevalence of shoulder pain, and musculoskeletal disorders surrounding the shoulder girdle can lead to degeneration of the shoulder joint. Estimating internal biomechanical forces and creating rehabilitation using this information could provide a way of reducing musculoskeletal pain in wheelchair users. Musculoskeletal modeling and AI could help provide new tools for that.
The main objective of this project is the development of neuromusculoskeletal modeling of upper-limb for rehabilitation during manual wheelchair in the 听simulator.
Contact e-mail: guillaume.durandau [at] mcgill.ca
Posted: September 8, 2025
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Thesis Project 2025-9
Title:听Development of a synthetic mucus for testing liquid biopsy samplers
Supervisor: Prof. Rosaire Mongrain
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: Endometrial mucus is collected for early detection of cancer using DNA content analysis. The quality and efficiency of the analysis is dependent on the amount of collected mucus. The liquid biopsy sampler has to be efficient in terms of absorption capacity (mass transport) and reproducibility. A phantom reproducing the clinical operation (pelvic organ and device navigation) has been developed. Simple synthetic fluids have used for the tests, however, mucus is a complex non-Newtonian fluid that exhibits shear- thinning behavior, with viscosity decreasing as shear rate increases. In order to better reproduce the physiological and clinical conditions, a new non-Newtonian synthetic mucus needs to be developed. The project involves the elaboration of synthetic mucus, its rheological characterization and constitutive mathematical modeling.
Contact e-mail:听rosaire.mongrain [at] mcgill.ca
Posted: September 12, 2025
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Thesis Project 2025-10
Title:听Simulating the future: high-fidelity insights into hydrogen flames
Supervisor: Prof. Hendrik Nicolai
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: The transition to renewable, carbon-free fuels is one of the most pressing challenges of our time. Hydrogen-based energy systems hold enormous potential, but they require a complete rethink of conventional designs 鈥 and we need to move fast. This project explores MicroMix hydrogen jet flames through high-fidelity simulations, providing fundamental insights into flame structures to develop the next-generation of models. Leveraging access to the exascale supercomputer resources, the project pushes the limits of clean energy research. If you enjoy programming and want to apply your skills to help shape the future of clean energy, then this project could be a great fit for you: reach out to me!
Contact e-mail:听nicolai [at] stfs.tu-darmstadt.de
Posted: September 18, 2025
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Thesis Project 2025-11
Title:听Rechargeable fuels of tomorrow: modeling metal combustion
Supervisor: Prof. Hendrik Nicolai
The term(s) to begin: Winter 2026, Fall 2026, Winter 2026
Brief description: Fossil fuels still supply nearly 80% of global energy, fueling climate change and energy insecurity. We urgently need disruptive alternatives. Metal fuels are emerging as one of the most radical options: carbon-free, fully recyclable, and capable of storing massive amounts of energy. When burned, metals release intense energy and form oxides that can be regenerated with renewable electricity, creating dense, safe, and transportable 鈥渞echargeable fuels.鈥 However, metal flames remain poorly understood: Extreme temperatures and strong radiation pose major challenges, while predictive simulations are still in their infancy鈥攁n urgent gap and a unique opportunity. If you are interested in programming, advanced simulations, and contributing to the future of clean energy, reach out to discuss this thesis opportunity.
Contact e-mail: nicolai [at] stfs.tu-darmstadt.de
Posted: September 18, 2025
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Projects for Winter 2025 and Fall 2025:
may or may not be still available - you may use contact e-mails to find out.
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Thesis Project 2024-2
Title: Multi-robot collaborative state estimation
Supervisor: Prof. James Richard Forbes
The term(s) to begin: Winter 2025, Fall 2025
Brief description: Autonomous vehicles, such as autonomous cars, trucks, and
trains, must fuse various forms of sensor data together in order to
ascertain their position, attitude, velocity, and angular velocity.
Typical sensor data includes inertial measurement unit (IMU) data and
some sort of position data, such as GPS data, or range data, such as
optical camera, radar, or LIDAR data. In multi-robot systems, an
individual robot can also utilize information from its neighbors by
having the robots communicate their state estimates. However, the
estimates of different robots are often correlated, and without
properly modelling these cross-correlations, the performance of the
estimator might be very poor. This project will then focus on
modelling those cross-correlations for collaborative state estimation
in multi-robot systems. The main task will involve the development and
coding of a sigma point Kalman filter to enable multi-robot
navigation; however, based on the student鈥檚 interests and background,
alternatives to the sigma point Kalman filter could be considered.
Students best fit for this project are those interested in using
mathematical tools, such as linear algebra, numerical methods,
probability theory, and numerical optimization, to solve problems
found in robotics. Experience with Matlab and/or C programming is
desired.
Contact e-mail: james.richard.forbes [at] mcgill.ca
Updated: May 2, 2023
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Thesis Project 2024-3
Title: Robot navigation
Supervisor: Prof. James Richard Forbes
The term(s) to begin: Winter听 2025, Fall 2025
Brief description: Autonomous vehicles, such as autonomous cars, trucks, and trains,
must fuse various forms of sensor data together in order to ascertain their position,
attitude, velocity, and angular velocity. Typical sensor data includes inertial measurement
unit (IMU) data and some sort of position data, such as GPS data, or range data, such as
optical camera, radar, or LIDAR data. This project will focus on sensor fusion for robot navigation.
The first task will be the development and coding of a matrix Lie group integrator,
in the spirit of a Runge-Kutta integrator, but tailor to matrix Lie groups. The second task will be
the development and coding of a cascaded sigma point Kalman filter to enable multi-agent navigation
(i.e., navigation of many robots). Students best fit for this project are those interested in using
mathematical tools, such as linear algebra, numerical methods, probability theory, and numerical optimization,
to solve problems found in robotics. Experience with python and/or C++
programming is desired.
Contact e-mail: james.richard.forbes [at] mcgill.ca
Posted: May 2, 2023
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Thesis Project 2024-10
Title:听Measurement transformation to enable linear robot navigation
Supervisor: Prof. James Forbes
The term(s) to begin: Winter 2025, Fall 2025
Brief description:听For a robot to execute practical听tasks, such as inspection of infrastructure, an accurate yet precise estimate of the robot's pose (position and orientation) from听sensor听measurements听is required. Pose estimation, which is a type of navigation, is inherently nonlinear. Although nonlinear pose estimation methods exist, a means to render the听pose estimation problem linear is attractive听due to the inherent simplicity of linear estimation problems. Recently in 听a transformation of the measurements was considered thereby realizing a linear pose estimation problem. This honours thesis project will build on Benahmed and Berkane 2024 by considering uncertainty quantification and robustness of the measurement transformation, as well as applications to alternative robot platforms.
Contact e-mail:听james.richard.forbes [at] mcgill.ca
Posted: October 13, 2024
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Projects for 2018-2019听school year:
may or may not be still available - you may use contact e-mails to find out.
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Thesis Project 2018-11
Title:听Dynamics of photon-driven lightsails for interstellar flight
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: The use of lasers to propel sails via direct photon pressure has the
potential to achieve very high velocity spaceflight, greatly exceeding
traditional chemical and electric propulsion sources, and enables the serious
consideration of interstellar flight.听 However, the dynamics and stability of
thin sails (lightsails) under intense laser illumination is an outstanding
problem.听 This project will examine the dynamics of very thin membranes both
theoretically and experimentally.听 The response of a lightsail to
perturbation will be analyzed both analytically and via computer simulation.
Use of gasdynamic loading techniques (shock tube) will enable the same
driving load to be applied in the laboratory, but without the use of
megawatt-class lasers.听 Experimental diagnostic techniques (photonic doppler
velocimetry, 3-D digital image correlation) will be developed to study the
lightsail dynamics that will eventually be applied to a laser-driven sail
proof-of-concept facility.
Personnel sought:听 Student should have a strong interest in advanced space
exploration concepts, with general background in physical optics, numerical
simulation, and experimental techniques.
Skills involved:听 Experience with photography and high-speed data acquisition
would be helpful.听 Completion of Mech 321 (Mechanics of Deformable Solids)
and Mech 430 (Fluids 2) is required for the project.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018
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Thesis Project 2018-12
Title:听Dynamic soaring on a shock wave
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: Dynamic soaring is a technique exploited by birds and sailplanes to increase
their flight speed by exploiting differences in airspeed of different masses
of air.听 This project will explore this approach by examining dynamic soaring
of a hypersonic glider on a shock wave.听 In essence, the technique consists
of 鈥渂ouncing鈥 back and forth from either side of a shock wave via a high
lift-to-drag turn, increasing the net velocity of the glider.听 The ability to
鈥渟urf鈥 on a very strong blast wave (such as resulting from a
thermonuclear blast or asteroid impact) from ground all the way to space will
be explored. The use of the technique on shock waves that occur in
interplanetary space (coronal mass ejections, etc.) that might enable
spacecraft to be accelerated to very high velocities 鈥渇or free鈥 will also
be explored.
Personnel sought:听 Student should have a strong interest in advanced space
exploration concepts and flight dynamics, with general background in
numerical simulation.
Skills involved:听 Completion of Mech 430 (Fluids 2) is required for the
project.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018
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Thesis Project 2018-13
Title:听Rapid transit within the solar system via directed energy:
laser thermal vs. laser electric propulsion
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: Directed energy in the form of a ground or space-based laser providing power
to a spacecraft is a disruptive technology that could enable a number of
rapid-transit missions in the solar system and interstellar precursor
missions.听 This project will compare two different approaches for a
spacecraft to utilize beamed laser power:听 (1) laser thermal propulsion,
wherein a laser is focused into a chamber to heat propellant that is expanded
through a nozzle and (2) laser electric propulsion, wherein a laser听 directed
onto a photovoltaic array generates electricity to power electric propulsion
(ion engine, etc.).听 These two concepts will be compared for a number of
missions of interest, as defined by NASA:听 (1) Earth orbit to Mars orbit in
no more than 45 days and (2) Traversing a distance of 125 AU in no more than
ten years.
Personnel sought:听 Student should have a strong interest in advanced space
exploration concepts, with general background in physical optics and
numerical simulation.
Skills involved:听 Prior exposure to spacecraft mission design (e.g.,
experience with 鈥嶬erbal Space Program, etc.) would be helpful.听 Completion
of Mech 430 (Fluids 2) and Mech 346 (Heat Transfer) is required for the
project.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018
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Thesis Project 2018-14
Title:听Impact of dust grain on lightsails for interstellar flight
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: Laser-driven lightsails are a promising technique for interstellar flight,
however, sails will experience impacts of dust grains in the interplanetary
and interstellar medium.听 The impact of a sub-micron grain can deposit as
much as 1 J of energy into the sail when travelling at speeds necessary for
interstellar flight.听 This project will examine the subsequent dynamics of
the sail and the damage incurred.听 This problem will be modelled both
analytically and numerically, and experiments will be performed in the lab
with gas gun-launched particles onto candidate thin-film materials.
Personnel sought:听 Student should have a strong interest in advanced space
exploration concepts, with general background in materials and stress/strain,
numerical simulation, and experimental techniques.
Skills involved:听 Experience with ANSYS would be very enabling for the
project. Experience with photography and high-speed data acquisition would be
helpful.听 Completion of Mech 321 (Mechanics of Deformable Solids) is required
for the project.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018
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Thesis Project 2018-15
Title:听Percolation model for detonation in a system of discrete energy sources
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: Detonation waves propagating in combustible gas mixtures exhibit very complex
dynamics, with transverse and longitudinal shock waves that sweep across the
front.听 This project will attempt to model this process by treating
detonation as an ensemble of interacting blast waves.听 Approximate, analytic solutions of
blast waves will be used to treat the problem.听 Results
will be interpreted with the assistance of percolation theory, a branch of
statistical physics.听 Results will also be compared to reactive Euler
simulations using supercomputing resources.
Skills required:听 Strong coding skills (language of your choice) and
awareness in advanced mathematics is of interest.
Personnel sought:听 Completion of Mech 430 (Fluids 2) is required for this
project. Interest in nonlinear physics and pattern formation in nature would
provide helpful motivation for this project. Exposure to concepts in
statistical physics (Ad. Thermo) is also desirable.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018
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Thesis Project 2018-16
Title:听Pellet stream propulsion for interstellar flight
Supervisor: Prof. Andrew Higgins
The term(s) to begin:Fall 2018, Winter 2019, Fall 2019
Brief description: A promising approach to deep space propulsion that may enable interstellar
flight is pellet stream propulsion, wherein high velocity pellets (with
velocity exceeding that of the spacecraft) are used to impart momentum onto a
spacecraft.听 Such a pellet stream may be able to be collimated and focused
over much greater distances than a laser beam, making it an attractive
alternative to laser-driven directed energy.听 This project will examine the
ability of a charged particle to be steered and re-directed via a static
magnetic field (e.g., quadrupole beam steering, etc.), both via computer
simulation and experimental testing in the lab.听 The ability to steer a small
(mm to cm scale) pellet via magnetic field of rare earth magnets at speeds of
~1 km/s would be a significant validation of the concept.
Personnel sought:听 Student should have a strong interest in advanced space
exploration concepts, with strong background in electromagnetism and physics.
Interest in or familiarity with conventional, fundamental particle
accelerators would be desirable.
Skills involved:听 Basic coding skills (language of your choice) and numerical
simulation is required. Experience with basic electronics and
microcontrollers (Arduino, etc.) and 3-D printing would be very helpful for
the project.
Contact e-mail: andrew.higgins [at] mcgill.ca
Posted: September 12, 2018