Grants and Contributions:

Grant or Award spanning more than one fiscal year. (2017-2018 to 2022-2023)

A Multiscale Approach to Catalyst Development for Hydrogen Production and Conversion Systems

The scientific objective of this research is the design of catalytically active layers that achieve the perfect balance between heat transfer, mass transfer, charge transfer, kinetic activity and catalyst lifetime. The results from this work can be used in many ways but I will focus on a number of sustainable technology applications involving hydrogen as a clean fuel and a resource that can be produced from renewable energy sources. Some examples are; improving the efficiency of hydrogen production by steam reforming of natural gas, biogas, or conventional liquid fuels through the use of optimized catalyst layers that maximize the delivery of heat to the reaction sites; storing renewable wind and solar energy by efficiently producing hydrogen by the electrolysis of water at catalytic layers at the electrodes in polymer electrolyte membrane electrolysers; using hydrogen to make clean electricity in fuel cells that have optimized catalytic electrode layers that cost less and last longer; using hydrogen in the isomerization of fatty acids on specialized catalyst layers that produce bio-oil products with a low enough freezing point that they can be used during Canadian winters. All of these applications involve the production or use of hydrogen to reduce greenhouse gas emissions, reduce the use of non-renewable resources and encourage the development of commercially competitive clean energy technologies. Canadians will benefit because the energy they consume will be generating fewer harmful pollutants and less greenhouse gas. By establishing a competitive edge in clean energy technologies, new commercial activity can be created in Canada that will result in high quality jobs being generated.

Furthermore, graduate students, undergraduate students and other researchers my labs will receive training in advanced multiscale mathematical modeling techniques that simulate the performance of catalytically active layers. These models will be able to predict the key transport properties (e.g., heat, mass, charge transfer) based on 3D reconstructions of the pore structure, size and shape of the particles and distribution of the active components in these catalyst layers. Other students and researchers will be trained in characterization techniques for evaluating the transport properties of thin porous layers as well as 3D imaging techniques for creating 3D reconstructions of thin layers of porous materials. These HQP will be highly employable as the modeling and characterization techniques are applicable in a wide range of industries and fields of research.