Թϱ prof leads global collaboration to advance net-zero hydrogen economy
Hydrogen is expected to play a crucial role in enabling countries reach net-zero emissions by 2050 – but the technological developments needed for a sustainable hydrogen economy require global collaboration and knowledge sharing, University of Toronto researcher Murray Thomson says.
Enter the Global Hydrogen Production Technologies (HyPT) Center.
Thomson, a professor in the department of mechanical and industrial engineering in the Faculty of Applied Science & Engineering, is one of four researchers leading the newly established centre – along with professors from Arizona State University in the United States, the University of Adelaide in Australia and Cranfield University in the United Kingdom.
The centre will advance net-zero hydrogen production technologies with the goal of making them more energy-efficient and affordable by reaching US$1 per kilogram. Researchers will also explore the social and environmental changes that are needed to build a global hydrogen economy.
“Our goal is to connect researchers and students worldwide to share insights and work synergistically to create a sustainable energy resource,” Thomson says.
“It is about connecting Canadians who work in hydrogen production and technology, but also connecting Canadians with researchers around the world, which I think is a great benefit to our students to promote new ideas, expertise and approaches.”
The Canadian component of the project will receive $3.6 million over five years from the Natural Sciences and Engineering Research Council of Canada (NSERC) to support student training and mobility.
Thomson’s research is focused on methane pyrolysis. He has co-founded a company, Aurora Hydrogen, which is creating low-cost, low-carbon hydrogen production.
“Aurora Hydrogen is growing very quickly,” he says. “We’ve hired 30 people and should have a pilot-scale plant built by the end of the year.”
He is also the methane pyrolysis leader of the new HyPT Center, overseeing one of three technologies the centre aims to advance. The methane pyrolysis subgroup includes researchers from University of Adelaide, University of British Columbia (UBC), Stanford University and University of Cambridge.
“Methane pyrolysis is a process that uses heat to break down natural gas into hydrogen gas and solid carbon particles, so that you don’t produce carbon dioxide. But that carbon is also a useful product,” says Thomson.
“My team at Թϱ is using microwave energy to break apart methane. Stanford and Cambridge are working more on the carbon byproduct side, while Adelaide and UBC are exploring different catalysts.
“We each have a different focus, but by interacting as a group we can work together to provide a more compelling technology.”
The other two hydrogen technologies the centre is exploring are water electrolysis, where water is split into hydrogen and oxygen using electrical energy; and photocatalytic water splitting, which uses sunlight to separate hydrogen and oxygen.
Since both methods require lots of clean water, the centre is also exploring challenges related to this crucial resource.
“Hydrogen production is expected to increase dramatically over the next decade,” Thomson says.
“We have a role to play in better training the next generation of students working in hydrogen energy, in developing the scientific foundations that these hydrogen production technologies are based on, and in ensuring our approaches consume less electricity, use better catalysts and make more efficient use of the carbon and oxygen byproducts.
“The goal is to provide the energy that the world needs with much less greenhouse gas emissions — that is the motivation.”