Professor Bri-Mathias Hodge

A major question looms over Colorado’s energy future: why does geothermal energy��—��a natural renewable resource��—��remain virtually untapped?��

�ʰ��Ǵڱ�����ǰ���Bri-Mathias Hodge, based in the Department of Electrical, Computer & Energy Engineering, along with Assistant Teaching �ʰ��Ǵڱ�����ǰ���Shae Frydenlund from the Center for Asian Studies, will examine the technological and social barriers that have held back geothermal development in Colorado.

Geothermal energy comes from the natural heat stored beneath the Earth’s surface. It’s harnessed by tapping underground reservoirs of steam or hot water to produce electricity or provide direct heating.

Colorado is home to significant geothermal areas including the areas of Mount Princeton Hot Springs, Waunita Hot Springs and the San Luis Valley��—��yet no geothermal power plants currently operate in the state. That could soon change, thanks to growing collaboration among researchers, energy companies and policymakers.

“We know there is an abundant amount of geothermal energy potential in our state,” said Hodge, who brings two decades of experience in renewable energy integration and power systems simulation. “What we need is a better understanding of the social, economic and regulatory factors that influence its development.”

Bridging technology and community

Assistant Teaching Professor Shae��Frydenlund

Frydenlund’s work with Indigenous communities in Indonesia, some of whom oppose geothermal projects due to environmental justice concerns, sparked an interdisciplinary collaboration with Hodge.

“I became very interested in bringing together physical science and social science perspectives,” Frydenlund said, “and to understand why a place as geothermal-rich as Colorado hasn’t tapped into this natural resource.”

Her research, together with Geography �ʰ��Ǵڱ�����ǰ���Emily Yeh, revealed that struggles over geothermal projects emerge in and through the politics of indigeneity, land tenure and uneven development.

“There are concerns over land rights, sacred territories, livelihoods and environmental justice,” she said. “We need to bring those perspectives as we think about using geothermal here.”��

To capture both the human and technical sides of geothermal development, the ̽����Ƶ team will combine tools, such as power systems modeling, spatial statistics and GIS mapping along with community forums, surveys and interviews. Gaining community input will be integral for this project.��

One of their main goals is to create an interactive map tool of Colorado showing potential geothermal sites, layered with data on social and technological factors.

“Just because an area has strong potential doesn’t mean it’s a good place to develop geothermal energy,” Frydenlund said. “If it’s not culturally appropriate or desired by the community, resources can be wasted and projects can fail.”

The issue isn't unique to Colorado.��

“We’ve seen this already in the U.S.," Hodge said. "Hawaii has been a leader in decarbonization goals and has great geothermal resources. Yet, there’s very little being developed there because you have to be mindful of the traditions in Hawaiian culture.”��

The planning phase for the project includes three major steps: campus-wide town halls to connect with geothermal experts, identifying industry and community partners across the state and gathering preliminary data through stakeholder engagement. Between January and March 2026, Frydenlund will conduct fieldwork at six sites across Colorado, including Steamboat Springs, Buena Vista and Sterling Ranch in the South Metro area.��

Building toward carbon neutrality

Geothermal exploration speaks directly to ̽����Ƶ’s goal of carbon neutrality by 2050 and the Western Governors Association’s��, which announced $7.7 million in funding in May 2024 to advance geothermal technology in Colorado.��

Geothermal technologies can operate at multiple scales from single buildings to community thermal networks to large-scale power generation.

“What’s really interesting from a power systems standpoint is that geothermal affects not only electricity supply, but also demand,” Hodge said. “If ground-source heat pumps became widespread, Colorado’s power grid could shift from a summer to a winter peak system.”

However, these technological advances alone can’t drive an increased transition to geothermal.��

“Understanding the intimate relationships that people have with land and with energy and with each other will make for a much richer picture of what kind of future geothermal energy has in this state,” Frydenlund said.��

The project is funded by a��Research & Innovation Office New Frontiers Grant.��