Abstract
Fischer-Tropsch (FT) synthesis is one of the largest-scale catalytic processes, where long-chain hydrocarbons are formed from syngas (CO and H2) by a combination of C-O activation and C-C coupling steps. Interest in sustainable aviation fuels is driving a renaissance of this century-old process. Typically, supported cobalt catalyst are preferred due to their high activity, selectivity towards long-chain hydrocarbons, and low CO2 selectivity. The nature of the active sites and the reaction network, consisting of C-O bond scission, C-C bond formation and hydrogenation steps, remain intensely debated, hampering the development of selective catalysts.
To investigate possible reaction mechanisms, a dual-site microkinetic model, agnostic to a preferred reaction mechanism, was constructed using reaction free energies and activation energies computed with VdW-DF density functional theory. To accurately capture the reaction environment, the effect of the CO saturation coverage was included in all calculations and in the microkinetic model construction. This approach proved to be critical to provide an accurate description of the kinetics under reaction conditions. Our first principles microkinetic model accurately captures the activity, selectivity and chain growth of the FT reaction.
Speaker Bio
Mark Saeys obtained his PhD from Ghent University in 2002. From 2003 to June 2014 he was a professor of chemical engineering at the National University of Singapore. Since July 2014, he is a full professor at the Laboratory for Chemical Technology at Ghent University, Belgium. During his PhD, he was a visiting scientist with Matt Neurock at the University of Virginia and with Bill Green at the Massachusetts Institute of Technology. For his work on gas phase radical chemistry, he received the ExxonMobil Chemical Benelux Award in 2002 and the Richard A. Glenn Award in 2003. In Singapore, he was the Associate Director for academics in the Singapore-MIT Alliance-Chemical and Pharmaceutical Engineering program and a visiting professor of chemical engineering at the MIT. In 2013, he received the prestigious Odysseus Award from the Research Foundation-Flanders to establish a research program on modelling-guided catalyst design at Ghent University. While in Singapore, he was one of the authors of the Carbon Capture and Storage/Utilization Roadmap for Singapore. In Belgium, he was a co-author of “The Chemical Route to a CO2-neutral World”, a Viewpoint published by the Royal Flemish Academy of Belgium. His research combines modelling-guided catalyst design with experimental kinetic validation and state-of-the-art characterization to unravel and optimize catalytic processes.
Abstract
Microfluidics exploits fluids and their physical and chemical properties at the microscale, enabling miniaturized platforms that offer lower cost, faster pace, higher performance, and increased portability than their macroscale counterparts. This talk will briefly discuss three research themes including droplet microfluidics, microwave sensing and soft robotic wearable systems.
- Two-phase droplet microfluidics employs monodispersed water-oil emulsions as mobilized test tubes to perform high throughput analysis (HTA). Despite numerous novel technologies reported, the adoption of droplet microfluidics as an HTA tool by non-microfluidics experts has not been seen. Modular-based droplet microfluidics, enabling easy assembly of application-specific systems, presents tremendous potential to break this barrier. This talk will introduce our work towards this goal including, a suite of physical models that can serve as design tools for passive-based droplet modules such as droplet generators, mergers, sorters and heaters, and a unique active droplet microfluidics method that relies on visual feedback of droplet position to actuate a pressure source to actively control individual droplets realizing functional modules.
- Simultaneous sensing and heating of individual droplets are critical but very challenging. Microwave resonators present tremendous potential to meet this need which will be the second part of this talk. Microwave sensing finds various applications beyond droplet microfluidics. Its applications for the detection of virus such as SARS-CoV-2 and E. coli as well as metal ions will be discussed.
- Soft robotic wearable systems offer hope to improve the quality of life for those in need because of their compliance nature. Most existing systems are expensive, power intensive and tethered to external power sources, limiting user mobility. Microfluidics enables miniaturization of the system including its front end (e.g. wearable sleeves) and back end (control unit), translating to low cost, tetherless and energy-efficient operation. This talk will present wearable sleeves for treating lymphedema, arthritis, and pressure ulcers due to the ill fit of prosthetic sockets.
Speaker Bio
Dr. Ren received her PhD in Mechanical Engineering from the University of Toronto and her master’s and bachelor’s degrees in Mechanical Engineering from Harbin Institute of Technology. She is currently a Professor of Mechanical and Mechatronics Engineering at the University of Waterloo (UW) and holds a Tier I Canada Research Chair (CRC) in Microfluidic Technologies. She is directing Waterloo Microfluidics Laboratory focusing on advancing fundamental knowledge of microfluidics and developing technologies that are impactful on a wide range of applications such as life science research, protein fractionation towards drug screening, water quality sensing and assistive technology for well-being. Besides the CRC, Dr. Ren has also received several awards from the engineering and research community, including: election as a Member of Canadian Institute of Engineering in 2024, election as a Member of Canadian Academy of Engineering in 2023, recognition as one of Canada’s 100 Most Powerful Women in 2021, election as a Member of the College of New Scholars, Scientists and Artists of Royal Society of Canada in 2018, being recognized as one of 20 leading female innovators in Women of Innovation (Dr. Ren is a co-founder of four start-up companies) in 2017.
Abstract
Biomanufacturing is a diverse industry, encompassing several well known processes such as antibiotics and fine chemicals. Canada has a long history of biomanufacturing which started in the 1920’s with the discovery of insulin for treatment of diabetes, launching what was the Connaught Lab which then went on to become part of Sanofi. Connaught Lab was also the first to develop combo vaccine making DPT in the 1940s and then playing a role in Polio vaccine development.
The talk will provide a flavor on the important groups of biologicals manufactured using animal/mammalian cells. Aspects of vaccine and antibody manufacturing as well as the advances in Cell and Gene therapy will be discussed.
Speaker Bio
Cynthia Elias is presently the Vice President, Operations at CCRM, Toronto. She has several years of experience in the field of animal/mammalian cell culture processes, including more than a decade of GMP commercial biological manufacturing at Sanofi. Prior to joining CCRM she held the position of Director, Manufacturing at the Government of Canada’s (NRC) Biological Manufacturing Center in Montreal, QC. Cynthia started in the Process development group at Sanofi working on new vaccines and clinical manufacturing and then moved on to commercial manufacturing. Cynthia was responsible for different departments within the bulk manufacturing of Inactivated Polio Vaccine (IPV). Before joining Sanofi, Cynthia worked at the National Research Council (NRC) in Montreal, in different positions of increasing responsibilities, from NSERC visiting scientist, Research Officer and Project Leader, leading a team working in the area of recombinant protein and viral vector production. Cynthia has experience in Biologics manufacturing from 5L to 1000L scale processes, including viral process for baculovirus, therapeutic cancer vaccines, AAV. Cynthia also has Regulatory and auditing experience with Health Canada, US FDA, and other regulatory agencies in Europe and other markets. Cynthia Elias holds a double Master’s and Ph.D. degree in Biotechnology from the University of Pune, India and, completed post-doctoral research at the Chemical Engineering Department, University of Colorado, at Boulder, USA. She has published several scientific articles in peer reviewed journals including book chapters and reviews. Actively involved in Biotechnology education programs in collaboration with the University of Toronto, York University (Markham Campus) and the University of Western Ontario (Adjunct Professor).
Abstract
The concept of oxy-fuel combustion involves using O2 separated from air to burn a fuel to generate a CO2 rich stream that can then be sequestered. However, if only O2 is fed into the boiler, the combustion temperature will be too high. In practice, flue gas would need to be cooled to condense out water and then a part of the CO2 rich flue gas is recycled and mixed with the O2 as the feed oxidant to the combustion system. The remaining CO2 rich gas (>90% CO2) can be compressed and sequestered or further purified and used as new uses for CO2 are developed.
There are three different combustion systems found in pulp mills:
- Kraft recovery boiler for burning black liquor
- Lime kiln for driving CO2 from CaCO3 to generate CaO
- Biomass boiler where bark and reject wood from pulping are burned
In this presentation I will talk about the early research in oxyfuel combustion in kraft recovery boilers and lime kilns and some of the process and process chemistry implications of transitioning from traditional combustion with air to oxyfuel combustion.
Speaker Bio
Nikolai De Martini is an Associate Professor of Chemical Engineering and Director of the Pulp and Paper Centre at the University of Toronto. He joined the faculty in 2017. Prof. De Martini earned a PhD in Chemical Engineering for work on nitrogen and sulfur chemistry in kraft recovery boilers at Åbo Akademi University in Turku, Finland. He currently leads the industrial consortium Effective Energy and Chemical Recovery in Pulp and Paper Mills which is supported by pulp and paper companies in Canada, the United States, Brazil, Chile, Finland and Sweden.
Abstract
Viruses are the most abundant microbial entity on the planet, impacting microbial community structure and ecosystem services. Viruses infecting bacteria and archaea have been specifically understudied in engineered environments. Using metagenomic and computational biology methods, we examined the diversity, host-interactions, and genetic systems of viruses across three North American landfills. From giant viral genomes to streamlined CRISPR-Cas systems, municipal landfills housed unique, and surprising viral ecology. Landfills, as heterogeneous contaminated sites with unique selective pressures, are key locations for diverse viruses and atypical virus-host dynamics.
Speaker Bio
Dr. Laura Hug: Associate Professor and Canada Research Chair in Environmental Microbiology. Department of Biology at the University of Waterloo.
Dr. Hug’s research examines the diversity and function of microbial communities in contaminated sites using a combination of ‘omics approaches and enrichment culturing. Current research in her group is characterizing the microbial communities colonizing municipal landfills, with foci on methane cycling, bioplastics degradation, and community interactions. Dr. Hug’s work has been featured in major news outlets including the New York Times, the Atlantic, Discover Magazine, and on Public Radio International’s “The World”. She was a featured scientist on a TFO children’s show and the BBC Radio 4 program, “Bacteria, the tiny giants” in 2023.
Abstract
Hydrogels have been widely used in a variety of biomedical and biosensing applications due to their favourable mechanical properties (mimicking those of soft tissues in vivo while facilitating high sensor flexibility), typically low non-specific protein adsorption (minimizing inflammation in vivo and reducing sensor interference), and capacity for controlling diffusion (enabling prolonged drug release in vivo and non-covalent biomolecule immobilization on biosensors). However, the elasticity of conventional pre-formed hydrogels limits their capacity to be injected or fabricated into various 2D or 3D geometries targeted for the development of functional sensor coatings and/or structured biomaterials. In situ-gelling hydrogels that can spontaneously gel following mixing of functionalized precursor polymers thus offer the potential to substantially expand the scope of feasible hydrogel applications. In this presentation, I will discuss recent work from our lab focused on designing and exploiting the properties of dynamically-crosslinked in situ-gelling materials based on poly(ethylene glycol) or zwitterionic polymer derivatives, enabling the rational design of injectable, printable, and/or processible hydrogels to address key challenges in tissue engineering and biosensing applications. In particular, I will discuss applications of our in situ-gelling synthetic hydrogels in creating injectable cell delivery vehicles for functional muscle regeneration, fabricating injectable in situ macroporous hydrogels for cell delivery, electrospinning nanofibrous hydrogel networks to create aligned/multi-cellular skin regeneration materials, 3D printing for creating microstructured cell therapeutics, and ink jet printing of surface coating-based platforms that can enhance both the specificity and selectivity of enzymatic, DNA, or aptamer-based biosensors.
Speaker Bio
Todd Hoare is the Canada Research Chair in Engineered Smart Materials and a Professor in the Department of Chemical Engineering at McMaster University as well as the Director of the NSERC CREATE Training Program for Controlled Release Leaders (ContRoL). Dr. Hoare’s work on “smart” environmentally-responsive hydrogels, in situ-gelling/printable hydrogel materials, and nanoscale drug delivery vehicles has been profiled by Popular Science, Maclean’s, and BBC for its potential in solving clinical challenges through innovative materials design. He is a Fellow of the International Union of Societies in Biomaterials Science and Engineering (IUS-BSE), was awarded an NSERC E.W.R. Steacie Memorial Fellowship (2018), has been cited as part of the 2018 Class of Influential Researchers by Industrial Engineering & Chemistry Research, and has received the 2016 Early Career Investigator Award from the Canadian Biomaterials Society and the 2009 John Charles Polanyi Prize in Chemistry in recognition of his research. He is also the co-recipient of the 2023 NSERC Brockhouse Prize for Interdisciplinary Research for his work in developing innovative drug delivery vehicles in collaboration with clinicians. Dr. Hoare is a past-president of the Canadian Biomaterials Society (2016-2017) and the Canadian Chapter of the Controlled Release Society (2013-2015), and is currently the Chair of the Macromolecular Science and Engineering Division of the Chemical Institute of Canada. He also serves as one of the Executive Editors of Chemical Engineering Journal (where he leads the applied polymer materials section) and is a member of the Editorial Advisory Board of Biomacromolecules.
Abstract
In research, we wonder, we re-examine dogma, we ask the “what if?” questions that lead to new insights and discoveries.
In business, we look for gaps, unsolved problems and intentionally develop solutions that fill a market need.
In this seminar, I will discuss both approaches in three stories. I will highlight how a series of “I wonder if?” questions led us to design a completely new way for target discovery and drug screening in cancer.
I will show how our new way to deliver therapeutics locally to the spinal cord and brain led to the invention of a new biomaterial that we have now tested clinically.
I will describe how we purposely designed a new vitreous substitute to overcome an unmet need and our path to translation.
Acknowledgements: The Shoichet Lab is grateful to have the opportunity to advance knowledge with exceptional researchers and collaborators and with the support of funding agencies: NSERC, CIHR, Medicine by Design-CFREF, Mend the Gap-NFRF, Krembil Foundation, DoD, ISRT, PRiME, among others.
Speaker Bio
Professor Molly Shoichet is University Professor, a distinction held by less than 2% of the faculty, and is Scientific Director of Precision Medicine at the University of Toronto, She is the inaugural Pamela & Paul Austin Chair in Precision and Regenerative Medicine. Dr. Shoichet served as Ontario’s first Chief Scientist in 2018 where she worked to enhance the culture of science. She has published over 800 papers, patents and abstracts and has given over 580 lectures worldwide. She currently leads a laboratory of 30 and has graduated 260 researchers. Her research is focused on drug and cell delivery strategies in the central nervous system (brain, spinal cord, retina) and 3D hydrogel culture systems to model cancer. Dr. Shoichet co-founded four spin-off companies, is actively engaged in translational research and science outreach. Dr. Shoichet is the recipient of many prestigious distinctions and the first person to be inducted into all three of Canada’s National Academies of Science of the Royal Society of Canada, Engineering and Health Sciences. In 2018, Professor Shoichet was inducted as an Officer of the Order of Canada and in 2011, she was awarded the Order of Ontario. Dr. Shoichet was the L’Oreal-UNESCO For Women in Science Laureate for North America in 2015, elected Foreign Member of the US National Academy of Engineering in 2016, won the Killam Prize in Engineering in 2017 and elected Fellow to the Royal Society (UK) in 2019. In 2020, Dr. Shoichet was awarded the NSERC Herzberg Gold Medal and won the Margolese National Brain Disorders Prize. In 2023, Dr. Shoichet was elected Fellow of the US National Academy of Inventors. Dr. Shoichet received her SB from the Massachusetts Institute of Technology (1987) and her PhD from the University of Massachusetts, Amherst in Polymer Science and Engineering (1992).
Abstract
Many chemical engineering courses are still delivered in the traditional course format of lectures with assignments and examinations as assessments. In addition, applications in the oil and gas industry are frequently used to illustrate concepts. This format and examples do not effectively engage many students. Creative ways of incorporating active-learning opportunities with relatable and/or diverse examples can improve the learning experience for undergraduate chemical engineering students. Details will be provided about an active-learning, technical elective course that uses coffee to illustrate and synthesize chemical engineering concepts; the students are literally able to taste their learning. Details will also be shared about the redesign of a fundamental course on mass transfer operations that features new examples, a case study, and in-class demonstrations.
Speaker Bio
Lauren Tribe has obtained an Honors Science degree in Biochemistry, a Bachelor of Engineering Science degree in Biochemical Engineering, and a Doctorate in Chemical Engineering from Western University and has been licensed as a Professional Engineering since 2006. She has been a faculty member at Western since 2001 and held administrative positions of Associate Chair, Undergraduate, of Chemical and Biochemical Engineering from 2015 to 2016 and Assistant Dean, First Year Studies, from 2016 to 2012. She has held special teaching roles at Western University as Experiential Learning Innovation Scholar 2020 – 2022 and Teaching Fellow 2022 – 2025. She has also received teaching awards in engineering in 2011 for the Maurice Bergougnou Teaching Award and in 2022 for the R. Mohan Mathur Award for Excellence in Teaching and then in 2023, the Edward G. Pleva Teaching Award for Teaching Excellence at Western University. Lauren is passionate about engineering and engineering education and has taught 56 courses to over 3,000 undergraduate engineering students over her career. She has developed opportunities for her students to be excited about their learning and to become engaged with experiential components in her courses. Examples include developing faculty-led study abroad courses to learn about engineering in a global context, an experiential course using coffee to synthesize chemical engineering concepts in a fun a relatable way, and incorporating examples and demonstrations to improve learning and understanding of mass transfer.
Abstract
As people spend most of our time indoors, exposure to indoor pollutants can have major health impacts. Indoor air quality (IAQ) also plays a significant role in cognitive performance and learning, making it particularly important in classroom environments. The rise in availability of low-cost air pollutant sensors provides a growing opportunity to leverage low-cost sensor measurements and big data analysis to assess IAQ and the impacts of building design on IAQ. In this study, we first evaluated the performance of different low-cost sensors (PurpleAir, QuantAQ MODULAIR-PM and MODULAIR) in both outdoor and indoor environments on the Georgia Tech Campus, by comparison with co-located research-grade instrumentation. Results highlight the direct impact of aerosol particle water on the low-cost sensor performance, in addition to the expected dependence on particle size distribution. A network of sensors was also deployed on campus beginning in Fall 2020, over an extended period (> 1 year) and across many buildings (> 20). This unique, continuous, and comprehensive data set allowed for investigation of the most important parameters that impact IAQ of various rooms and building designs. The data were used to train and test a Tree based machine learning model, which had high prediction accuracy for indoor pollutant levels. Various building design factors such as ventilation type were identified important predictors of indoor pollutant levels. Overall, results from this study provide data-driven insights into what types of environments different sensor types are best suited for, under what aerosol conditions they face the most limitations, and indicate that outdoor low-cost sensor networks may provide sufficient data to evaluate indoor pollutant concentrations across a wide range of buildings.
Speaker Bio
Dr. Nga Lee “Sally” Ng is the Love Family Professor in the School of Chemical & Biomolecular Engineering, School of Earth & Atmospheric Sciences, and School of Civil & Environmental Engineering at the Georgia Institute of Technology. She earned her doctorate in Chemical Engineering from the California Institute of Technology and was a postdoctoral scientist at Aerodyne Research Inc. Dr. Ng’s research focuses on the understanding of the chemical mechanisms of aerosol formation and composition, as well as their health effects. Her group combines laboratory chamber studies and ambient field measurements to study aerosols using advanced mass spectrometry techniques. Dr. Ng serves as the Editor-in-Chief of ACS ES&T Air. Dr. Ng’s research contribution has been recognized by a number of awards, including the Sheldon K. Friedlander Award and the Kenneth T. Whitby Award from the American Association for Aerosol Research (AAAR) and the Ascent Award from the American Geophysical Union (AGU). Dr. Ng is currently leading collaborative efforts to establish the Atmospheric Science and mEasurement NeTwork (ASCENT) in the US.
Abstract
Electrocatalysis has the potential to revolutionize the production of chemicals and consumer goods in an environmentally sustainable manner, by replacing traditional fossil fuel based processes with energy-efficient technologies powered by renewable electricity. This approach also holds great promise in addressing global challenges related to the remediation of per- and poly-fluoroalkyl substances (PFAS) water pollutants. To be successful, electrocatalytic processes must employ nonprecious nontoxic materials, utilize aqueous environments, consume minimal energy, and effectively eliminate harmful chemicals. Achieving functional electrocatalytic processes necessitates a comprehensive understanding of mechanisms and the strategic design of nanomaterials with controlled properties. In our approach, we employ pulsed laser in liquids synthesis for the development of nanocatalysts with controlled surface chemistries, to facilitate a quantitative mechanistic understanding of electrocatalytic processes, particularly within the anode microenvironment. For example, laser-made earth-abundant mixed-metal nanocatalysts on high-surface-area carbon supports selectively electrooxidized toluene to benzyl alcohol with unprecedentedly high activity. For PFAS remediation, we achieved complete defluorination of perfluorooctane sulfonate and GenX in aqueous electrolytes with laser-made bimetallic nanocatalysts. My group’s overarching goal is advanced design and fabrication of nanocatalysts for the electrocatalytic generation of oxidants and reductants from water, predicated on a detailed atomistic understanding of mechanisms and nanomaterials, with the ultimate goal of driving forward scalable sustainable solutions for chemical manufacturing and water remediation.
Speaker Bio
Astrid M. Müller is an Assistant Professor of Chemical Engineering at the University of Rochester since 2018. Prof. Müller earned a PhD in Physical Chemistry for work on ultrafast reaction dynamics at the Max Planck Institute of Quantum Optics. Her postdoctoral work centered on developing a fundamental understanding of laser–matter interactions. Her independent research focuses on pulsed laser in liquids synthesis of mixed-metal nanomaterials with controlled structural and electronic properties. This uniquely positions Prof. Müller’s group to quantitatively understand how nanocatalysts and electrocatalytic mechanisms impact the performance of nanomaterials in sustainable energy, green chemistry, and aqueous PFAS destruction applications.