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Deep beneath the Earth’s surface lies an almost endless supply of energy. Gordon Brasnett remembers even as a child being intrigued by the possibilities. “Family camping trips where we visited hot springs in Alberta and B.C. probably reinforced this interest,” he says.

Today, as the world looks for ways to reduce its reliance on fossil fuels, geothermal energy holds great promise as an alternative, especially in western Canada. But tapping the resource won’t be easy or cheap. Brasnett, a geophysicist who graduates this fall with a (SEDV) from at the ����ɫ��, tackled a big question: Where in Alberta are the most economically viable locations to build new geothermal projects?

His answer, created as a toward his degree, includes a that considers the economic viability of particular areas across Alberta for future geothermal development. His visualizations draw on a matrix of data sources, such as pioneering research by University of Alberta scientist who estimated the drilling depths required to reach progressively hotter geothermal sources. ��

Mapping the potential for future projects

Brasnett’s interactive model looks at all of Alberta, illustrating the geothermal depths yielding temperatures between 40°C and 80°C — for direct-heating uses such as warming buildings or greenhouses — and temperatures between 120°C and 150°C — hot enough to generate electricity as well as ambient heat.��

He continues: “The regions with the highest gradients and therefore the shallowest estimated depths to 120°C are found west of Zama City, east of Rainbow Lake, and north of Rimbey. The estimated depths to reach 120°C in these areas are in the range of 2,250 to 2,800 metres.” ��

Finding an optimal geothermal location means balancing other factors too, such as: distance to where heat energy can be used, up-front costs of drilling and construction, and opportunities to generate future revenue. “My model showed that the regions with the highest gradients may not necessarily be the cheapest areas to develop for a project, as they may be too far from existing roads, transmission lines, and customers to use heat. As a result, the model showed that areas closer to Grande Prairie, Fox Creek, and Lacombe may be developed more economically for a 120°C project.”

Brasnett hopes his map helps spark conversations and inspire site-specific feasibility studies by remote municipalities and other early geothermal adopters. “In my opinion, the early adopters of geothermal projects will be people who need large quantities of heat, but who don’t want the greenhouse gas emissions or price uncertainty associated with burning hydrocarbons.

“This could be people developing district heating systems for warehouses, industrial parks, office parks, campus spaces, greenhouses, or residential buildings.”

New engine for economic growth

Alberta has a successful history of applying innovation and technology to resources such as agriculture and the oilsands. Brasnett believes geothermal energy can grow into a new economic engine.

His interest in the field led him to study in ����ɫ�� multidiscipinary SEDV program, offered through the School of Public Policy, Haskayne School of Business, Schulich School of Engineering, School of Architecture, Planning, and Landscape, and Faculty of Law. In the 16-month professional master’s program, SEDV students learn about energy systems, both current and future, through the lenses of technology, policy, business, and social impact. Students in the program build skills in collaboration, teamwork, communication, and research, enabling them to advance their careers across the energy sector. The emphasis is on developing energy projects that maximize social and economic benefits, and minimize negative environmental impacts.

Students like Brasnett are watching closely as the first large-scale geothermal projects take shape. For example, the a partnership developed by Terrapin Geothermics near Grande Prairie, will contribute clean geothermal energy to the grid while supplying heat for local industry. The Indigenous-led partnership near Fort Nelson, B.C., is developing geothermal heat from a depleted natural gas field to support electricity, agriculture, and other local initiatives. The project by Novus Earth Energy near Hinton focuses on renewable energy and food security. is testing its ultra-deep, closed-loop geothermal drilling system

Opening new doors

The SEDV program opened new doors for Brasnett. The research capstone project is a core part of the curriculum, where students apply concepts learned in the program to a real-world question, in partnership with industry, NGOs, government, and academic partners. His research project was supported by the His supervising professor was director of the Energi Simulation Centre for��Geothermal��Systems Research at UCalgary. For the project they collaborated with Dr. Catherine Hickson, CEO of the Alberta No. 1 Geothermal Energy Project.

“There are a lot of interesting pilot projects around the world today that may kick off a flurry of development throughout the 2020s in countries where geothermal is still a new technology,” Brasnett says. “I’m optimistic that Alberta can be a leader in this space given the geoscience, engineering, drilling skills, and technologies that the oil and gas sector has developed over the past 60-plus years.”