Enhanced Geothermal Systems: Unlocking Earth's Hidden Energy Potential

Enhanced Geothermal Systems: Unlocking Earth's Hidden Energy Potential

Robert Rapier  Senior Contributor

Robert Rapier is a chemical engineer covering the energy sector.

Dec 7, 2024,06:53pm EST

Enhanced Geothermal Systems (EGS) are quietly transforming how we think about renewable energy, turning one of the Earth's most underutilized resources—its internal heat—into a reliable and sustainable power source. The DOE Department of Energy (DOE) has estimated that there is approximately 100,000 megawatts of clean, baseload power possible through EGS technology in the United States

The beauty of this technology, which extracts thermal energy from deep beneath the surface, is that it is widely applicable, and may be of particular interest in regions where wind and solar face limitations.

Harnessing Earth's Internal Heat

EGS operates by drilling deep into the Earth's crust to access hot, dry rock formations. By injecting water into these formations and creating fractures, a closed-loop system is established. The water circulates through the hot rock, absorbing thermal energy and transforming into steam. This steam is brought to the surface to drive turbines, generating electricity. The cooled fluid is reinjected underground, minimizing environmental impact and sustaining the process.

This differs from traditional geothermal energy, which relies on natural reservoirs of hot water or steam. EGS's ability to artificially create geothermal reservoirs means it can be deployed in regions where conventional geothermal resources are unavailable, dramatically expanding the potential application of this renewable technology.

Reliable Baseload Power

One of EGS's standout features is its ability to provide baseload power. Unlike wind and solar, which are intermittent and depend on weather conditions, EGS generates firm power, producing electricity around the clock.

This consistent power output makes it an excellent complement to intermittent renewable energy sources, reducing reliance on costly and complex energy storage solutions.

Fervo Energy is pioneering advanced techniques adapted from the oil and gas industry, including horizontal drilling and well stimulation. Its Utah project, set to produce 320 megawatts of electricity by 2028, is a landmark in renewable energy innovation. This project has already attracted attention from Southern California Edison, which has committed to integrating Fervo's geothermal energy into its grid.

Ormat Technologies has received a nearly $3.4 million grant from the DOE to demonstrate the viability of EGS at its Brady facility near Reno, Nevada. The project aims to improve non-commercial wells by applying EGS stimulation techniques to develop fracture networks that will enable communication with productive reservoirs and enhance electricity generation.

The project builds on Ormat's previous EGS work, including a demonstration at the Desert Peak geothermal power plant, which is set to be the first application of EGS technology to supply a producing power project in the U.S. Ormat's air-cooled power plants are particularly well-suited for EGS developments due to their compatibility with typical production temperatures and their water-conserving design, which re-injects all geothermal fluid back into the ground.

Cornell University is exploring EGS for district heating with its Earth Source Heat Project. This initiative aims to provide carbon-neutral thermal energy to the university’s campus, demonstrating how EGS can serve localized heating needs while supporting decarbonization goals.

Advancements and Opportunities

Recent advancements in drilling technology have significantly reduced the costs associated with EGS, making it more competitive with other renewable energy sources. Innovations like synthetic diamond drill bits and horizontal well systems have enhanced efficiency, enabling faster project development.

Additionally, federal and state policies promoting renewable energy integration are creating opportunities for EGS expansion. Enhanced mapping of geothermal potential by agencies like the National Renewable Energy Laboratory (NREL) has revealed viable sites across much of the U.S., further broadening EGS's appeal.

A Critical Component for the Future of Energy

Enhanced Geothermal Systems represent a potentially intriguing component of future clean energy production. Their scalability, reliability, and minimal environmental footprint make them a valuable addition to the renewable energy mix.

As technology continues to advance and costs decline, EGS has the potential to play a leading role in the global shift toward sustainable energy, providing solutions that meet both electricity and heating needs while combating climate change.

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Attached is the summary of a study of geothermal by UT

Attachments:

Thanks, Walker.  The recently published US map showing areas that are prospective for geothermal includes the entire Ark-La-Tex region.  The question may end up being a political one in an area where new electric generation may turn into a competition between geothermal and natural gas fired generation particularly for site specific applications like data centers.

In rural Colorado, these abandoned oil wells could soon be used to ...

One way to cut the cost of geothermal energy: Use former oil wells instead of drilling.

BY Adele Peters  fastcompany.com

Outside the small town of Pierce, Colorado, a group of old wells were shut down six years ago when they stopped producing oil. But a startup now wants to repurpose the wells for a geothermal energy system that could help heat local homes.

Building new geothermal power—a type of clean energy that uses heat from underground to produce electricity or heating and cooling—is usually expensive because of the need to drill deep below the ground. That’s why Gradient Geothermal wants to reuse existing wells.

“If you can remove the cost of drilling through the use of facilities that are already there, you go a long way toward making geothermal a really inexpensive way to access the heat that’s in the earth,” says Benjamin Burke, Gradient’s CEO.

The wells on the site are 9,000 feet deep. The amount of heat at a given depth varies depending on location—Nevada, for example, has more geothermal potential than Colorado. But the site in Pierce “is at a depth where there’s plenty of heat for the town,” Burke says.

Gradient Geothermal is one of several companies to get state grants to test various approaches to adding geothermal energy in Colorado. Over the next several months, the startup will be studying the feasibility of the system for the site, looking at what it would take to build, how many buildings it can support, the cost, and the potential greenhouse gas emissions reductions. Already, the company has piloted the reuse of oil wells on another 40-year-old oil field in Nevada that’s still in operation; in that case, the energy is being used to help power the oil company’s operations.

In Pierce, when the oil wells shut down, they were producing only around 2% oil and 98% hot water. If Gradient’s plan moves forward as it envisions, it will harness that hot water and send it to a central facility where the heat is exchanged with a separate system of pipes that run in a network around the town, heating and cooling homes and other buildings, including a school and a meatpacking plant. (The geothermal power will also provide a small amount of electricity to power the company’s own operations.)

Even the town’s sidewalks could potentially be heated, removing snow and ice in the winter. Gradient is partnering with other companies that helped design a geothermal heating network for Colorado Mesa University. Installing the piping would be relatively inexpensive, Burke says, and the project could likely be supported through a mix of funding, including state and nonprofit grants.

“Right now [the town] heats with predominantly natural gas, and sometimes wood stoves,” says Johanna Ostrum, Gradient Geothermal’s COO. “So, our goal here is to provide a benefit, create an opportunity for the town, and really build a pathway for emissions reduction.”

Operating a geothermal plant uses similar skills as working in oil and gas, Ostrum says, and the facility could provide new local jobs for people who previously worked in the oil industry. “The town is looking for growth and new businesses, so they view this as an opportunity to develop and potentially add new jobs,” she says.

In a separate project that also received a state grant, a company called Geothermal Technologies is exploring the possibility of drilling new geothermal wells on a local dairy farm to help provide electricity for the town.

Gradient’s feasibility study will run until next fall, and then the project would have to get funding to move forward. But the model could eventually be replicated. Chevron, which owns the oil field, is partnering on the project with an interest in potentially using the approach on some of its other sites, some of which might also be able to help power nearby communities.

“A lot of the oil fields in the United States have small towns in and amongst them,” Ostrom says. By some estimates, there are between 2 million and 3 million abandoned oil wells in the U.S.

Fascinating technology and discussion. Here in NW Louisiana we have many abandoned wells that seemingly would be ideal for harnessing this form of energy. Wonder how the economics would work for making this a viable, new energy source. Would existing O/G companies pivot and retrofit abandoned wells or would new entrepreneurs be enticed to purchase/lease these abandoned wells and proceed independent of the O/G industry? Will this be profitable to the developers and affordable to the end users? Would current mineral rights owners benefit in any way? Lots of unanswered questions. Thanks for posting.

Good questions all, Les.  Let's start with the fact that Haynesville wells have bottom hole temps that are hot enough for geothermal.  At this point I'm unsure if the existing wells are correctly connected as is for geothermal.  If they are or can be refracked to communicate correctly, that would be ideal but even if new wells needed to be drilled it could be profitable.  I expect all Haynesville operators are aware of the potential.  If they don't want to fund the work, I think investors would be interested as would operators of plants that need the uninterrupted, reliable electricity generated.  The Data Center in Richland Parish being a good example but other industries requiring significant electric service could be potential users whether they fund the projects themselves or sign usage agreements with investors.  Thanks for contributing to the thread.

The Future of Geothermal Energy

https://www.iea.org/reports/the-future-of-geothermal-energy?utm_cam...

Highlights:

  • Today, geothermal only covers about 1% of global electricity consumption, but new technologies mean it could meet 15% of global electricity demand growth between now and 2050 if project costs continue to decline. That would give it the third largest share of global electricity generation growth after solar and wind.
  • This would involve the deployment of as much as 800 gigawatts of geothermal capacity worldwide, delivering annual output equivalent to the current electricity demand of the United States and India combined.
  • The report finds that policy and regulatory measures could enable geothermal costs to fall by 80% by 2035. This would put geothermal on a par with existing hydropower and nuclear plants – and it would also be highly competitive with solar PV and wind paired with battery storage.
  • The oil and gas industry can play a key role in making geothermal more competitive. Up to 80% of the investment required in geothermal involves capacity and skills that are transferrable from existing oil and gas operations
  • The total investment in geothermal could reach $1 trillion by 2035 and $2.5 trillion by 2050. If next-generation geothermal grows strongly in the coming years, employment in the overall geothermal sector could increase sixfold to 1 million jobs by 2030, according to the report.
  • At a time when the digital economy and artificial intelligence applications are growing strongly, geothermal has strong potential to help power the increasing number of large data centres that underpin the tech sector.

Skip, all - the specific heat requirements escape me, but my recollection is that a small scale system using Ormat's ORC based systems would need like 50,000 bbls/day of high temperature water, continually, to generate in the low 10-20 mW range.  The typical Haynesville wells are too dispersed, and the water rate falls off quick enough that getting to scale would require new technology and a lot of investment.  

https://www.ormat.com/en/home/a/main/

Hey, dbob. Unlike many Ark-La-Tex conventional reservoirs like the Smackover and Cotton Valley, the Haynesville Shale is dry as a bone except for the frack water used to hydraulically stimulate the rock.  The bottom hole temps, especially in the southern reaches of the fairway are approaching 400 degrees F.  A geothermal plant could use the Haynesville in a closed loop system with water from another source like the Red River.  The US geothermal map shows most of NW LA and indeed the Ark-La-Tex as an area with the right ingredients for geothermal.

GEOTHERMAL%20US%20MAP.pdf

Still not getting notices of these new posts. 

Accidentally found this one and "followed"

Thanks, I'll let Keith know.  Again.

There have been several articles in Houston and Austin papers on geothermal drilling in Texas.  Bedrock energy is now drilling wells to supply a new office building in Austin.  Below is their website, which is interesting.

https://bedrockenergy.com/

Thanks, phoenix.  Geothermal should be a clean energy source that the O&G industry prioritizes for certain applications.

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