The Quest For Renewable Baseload Power
As solar and wind energy grow, we are still highly dependent on fossil fuels for our global energy mix, when including transportation, manufacturing, shipping, fertilizer production, etc.
Partially, this is due to mankind’s enormous hunger for energy, with a constantly growing consumption since the 1900s.
A few other factors play a role as well. The first is that solar and wind have become cost-competitive with fossil fuels only recently. So there is a lot of catch-up to do in terms of investment and energy infrastructure that will take years and decades to achieve.
Another second factor, more problematic, is that wind and solar are inherently intermittent energy sources.
So, as they are becoming a larger and larger part of the electric grid, they are increasingly required to be coupled with expensive energy storage systems, from batteries to pumped hydro or compressed, something we covered in more detail in “The Future Of Energy Storage – Utility-Scale Batteries Tech” and “Non-Chemical Alternatives To Batteries For The Energy Transition.”
Base Load Power Options
Hydropower is maybe the only baseload/deliverable on-demand renewable energy, but it is limited in scope by natural resources and geography, with most of the potential already in use.
Another carbon-neutral option that is making a comeback is nuclear power. It is also good at providing baseload power no matter the weather (although drought can reduce output)
This is in large part driven by technological innovation, from SMRs (Small Modular Reactors) to 4th generation reactor designs (follow the links for full reports on these topics). In addition, AI companies like Microsoft are closing nuclear power deals to secure electricity for their AI data centers for the next 2 decades.
But nuclear energy is still controversial, potentially dangerous, and unlikely to dominate the energy mix of many countries skeptical of this technology.
There is a 4th form of renewable energy, besides solar, wind, and hydropower, that has been barely tapped so far: geothermal energy.
Geothermal Energy
All other forms of renewable energy are ultimately solar energy, including wind and hydro (rain) created from the weather patterns powered by the Sun.
But geothermal energy is different, with it being powered by radioactive reactions at the core of the planet. As this heat slowly emerges from the depth of the Earth, it is remarkably stable and predictable.
Depending on the technology used, it is even possible to postpone by a few hours the conversion of geothermal heat -> electricity. This makes it a perfect complement to wind and solar, with geothermal able to pick up the slack when they are underperforming.
Like all other renewable energy forms, the potential for geothermal energy is very location-dependent. Interestingly, this can be located in regions that are otherwise poor in energy resources, both renewable and fossil, like for example Central Europe and Japan.
Judging The Potential of Geothermal
Geothermal energy depends on the temperature of the underground layers of rocks. This can vary greatly, with volcanic or mountainous regions being much hotter, as well as any area with seismic activity.
Another factor, at least for deep drilling, is the presence of underground water and the permeability of the rock. The more, the better, as it allows for heat to be conducted quicker and over a greater distance around the drill site.
In a 2020 study by the CNR in Italy, titled “Predicting geographical suitability of geothermal power plants”, a global map of geothermal potential was drawn (see above).
When zooming on the USA, we see that most of the geothermal potential is located in the West of the country, also some segments of Texas and Louisiana are interesting.
In Europe, the geothermal potential is strong as well and distributed throughout the continent. Interestingly, is it especially strong in the industrial centers of the Rhine Valley and Central Europe. The center of Italy has also a potential almost as high as Iceland, notoriously advanced in geothermal energy, with other notable points being Corsica, Portugal, and Greece.
In Asia, nations in the “Ring Of Fire” (Japan, Indonesia, etc.) around the Pacific Ocean have the largest potential.
Scale Of Geothermal Energy
When talking of geothermal energy, we need to distinguish between 3 levels of depth and, therefore, technical complexity and energy.
Shallow Heat Pump
Geothermal heat pumps are now a somewhat common system in many countries. The idea is not so much to tap into geothermal energy than to use the capacity of the ground to stay at a constant temperature and have a lot of thermal inertia.
If the ground is deep enough, its temperature becomes the year’s average. This means you can extract heat from it in winter and cold in summer.
There are many variants of this technique, depending on how the loop to extract heat from the ground is built.
While most systems use a heat pump to maximize the energy transfer and save energy, it is also possible to use a passive geothermal system, notably to heat greenhouses as we discussed in “Geothermal And Passive Greenhouses – Reducing Farming Carbon Emissions”.
Deep Geothermal Energy
This is usually when heat is extracted from depths of 500m or deeper (1,640 feet). At these depths, the temperature increases steadily for every kilometer of extra depth, depending on the local geothermal resources.
In England, the average subsurface temperatures at 1000 m, 3000 m, and 5000 m are around 40°C, 90°C and 140°C.
Usually medium-depth, as in “only” 1,000-2,500 meters (0.6-1.5 miles) are usually drilled for heat production only, like for directly heating buildings or industrial facilities, especially through district heating (centralized heating for a whole block for example).
For example, Paris Orly Airport in France extracts 300 cubic meters of water at 74°C. This generates a thermal output of 10 megawatts, reducing fossil fuel consumption by an estimated 4,000 metric tons of oil equivalent per year.
Ultra Deep Geothermal Energy
This can also be called high-temperature geothermal energy.
Below 3,000 meters, drilling can become more complex, as the rock will usually start to go above boiling water temperature, pressure increases, and more advanced drilling machinery is required to survive the extreme conditions.
This is also where the heat is the most intense, allowing for the maximum energy production, including electricity generation.
Producing Power With Geothermal Energy
While still niche in most of the world, a few countries have demonstrated the potential of geothermal energy in power production. Notably, Kenya (50% of national power generation), Iceland (30%), and the Philippines (17%).
In some of these cases, like Iceland, it can even be argued that more could be extracted if there was a way to export it abroad. Many nations like the USA, Japan, France, and Italy have very large untapped geothermal potential.
In most cases, the ultra-hot water (>150°C) can be used for both electricity generation and co-generation of heat as well.
Traditional, Enhanced & Advanced Geothermy
Traditional Geothermal
Traditional geothermal energy generation relies on finding the perfect situation of hot enough rocks, preexisting water, and high rock permeability.
This is indeed the ideal situation, but this is also what has hindered the development of geothermal energy. The risk of drilling and not finding rock, or the right permeability could kill a project and generate massive financial loss.
So traditional geothermal drilling is not very different from oil drilling, where the often poorly understood underground geology determines the economic viability.
Enhanced Geothermal
In contrast, enhanced geothermal techniques use “hydraulic stimulation.”
The idea is to inject water into the rock layer’s preexisting cracks to increase permeability. What differs from fracking in oil & gas extraction is that it does not require the creation of additional fractures (fracking), nor to use frack sands to maintain the fractures in an open state.
In theory, enhanced geothermal power can be used everywhere in the world. In practice, the ideal conditions are deep granite covered by a 3–5 kilometers (1.9–3.1 mi) layer of insulating sediments that slow heat loss and located in high-temperature regions.
Still, enhanced geothermal can radically increase the potential site for geothermal activity, and maybe more importantly, generate a much more predictable output.
Advanced Geothermal
Closed Loops
Some researchers and companies are looking to go a step beyond enhanced geothermal. Instead of injecting water and collecting it back, they want to develop a fully closed-loop system.
In theory, a closed loop system could be installed anywhere, with only the local rock temperature and depth varying the final energy output.
Supercritical Geothermal
The idea here is to tap into super hot rocks at 400°C. At these temperatures, the reservoir liquid is expected to be supercritical, a matter state where gas and liquid states merge.
Supercritical liquids can contain 4-10x more energy than normal ones. So where a 200°C EGS project might have a capacity of 5MW, a 400°C supercritical project would have ten times that capacity at 50MW. Three 400°C wells would have a larger capacity than 42 200°C wells.
The Iceland Deep Drilling Project (IDDP) is the most prominent project in that field, although there have not been many updates since 2022.
Another company working on this project is Quaise. They are developing a microwave ‘gyrotron-powered drilling platform’ that vaporizes boreholes through rock. They plan to use the technology to reach a depth of 20km and access 500°C heat, or “terawatt-scale power”, with the open goal of replacing all baseload power with supercritical geothermal energy.
Minerals Extraction
In some cases, the underground water that is extracted for its heat is also rich in dissolved brine. These brines can be abundant in useful minerals, and as the extraction process is already done, it provides a complementary revenue stream to the geothermal energy producer.
For example, the company Vulcan Energy (VUL.AX) is looking to generate heat and power, as well as lithium from underground brine in the Rhine Valley (see more about Vulcan below).
Co-Generation
The heat produced with geothermal energy is usually either used as heat for housing or for producing electricity.
However, other applications could be developed to maximize the use of energy on-site, especially in remote locations. For example, it could be used to desalinate seawater or produce hydrogen and/or ammonia, which could then be exported where it is needed.
Geothermal Economics
Geothermal energy is overall a relatively cheap energy source. The market is expected to grow by only 3.14% CAGR in the 2023-2033 period.
One advantage of this technology is that it leverages decades of experience in drilling in the oil & gas industry. In practice, it could also be a good way to maintain employment and the technical skills of oil workers during the green transition.
When compared to other energy sources, geothermal holds its own against solar + energy storage at the utility scale.
And that’s without taking into account that geothermal might be better suited to regions with poor solar potential, or with massive heat and energy demand in cold winters when solar is producing the least (like Germany, Norway, and some parts of North America).
So geothermal energy generation can be profitable. It is however suffering from the need for massive upfront investments, with the return on the initially spent capital likely taking a decade or two.
This is also a type of green energy poorly covered by subsidies, tax incentives, and overall green policies, that have historically favored solar and wind (see the graph above to see the effect of subsidies in making geothermal more expensive than solar).
With the need for storage and the issues related to solar & wind intermittency coming at the forefront of policymakers’ awareness, this might change.
Geothermal’s Pros & Cons
The Best Green Energy?
Geothermal energy is truly renewable, while also being easy to produce on demand and stable throughout the day and year, making it a good equivalent for hydropower more than solar or wind.
Another advantage over all other renewables (including hydro) is a very limited land footprint, with most of the facilities invisible underground. This leads to minimal ecological and environmental disruption, where the same capacity would have covered hectares in solar panels or wind turbines or under the water of a dam.
Lastly, geothermal energy mostly uses drilling technology used by the oil & gas industry. If anything, this is a technology most advanced in Western countries, reducing drastically the risk of dependence on supply chains located in China, as in the case of solar panels, wind (rare earth magnets), and batteries.
Geothermal Problem
Resource Depletion
Underground heat does replenish over time. However, geothermal heat extraction can remove heat quicker than it is accumulating.
So the real rate of production should be calculated to either avoid depletion totally or to incorporate that the resources need a production pause of a few years /decades after 30-50 years of extraction.
Earthquake Risks
Any drilling, especially one affecting deep underground water layers, can theoretically cause earthquakes. For example, a geothermal energy project triggered a damaging 5.5 magnitude earthquake in 2017 in Pohang, South Korea.
This is mostly due to the same phenomenon causing fracking to be linked to earthquakes. By adding fluids underground, the process lubricates the rock layers, making it easier for them to move.
Overall, these earthquakes are not enormous but can be damaging locally.
So in some cases, especially in very seismically active regions, it could be best to produce power with geothermy in relatively remote or uninhabited regions.
Alternatively, seismic but geothermally rich regions might benefit best from closed-loop designs, that do not disturb the rocks past the initial drilling, nor inject water in the underground rock layers.
Investing In Geothermal Energy
The sector is still relatively small compared to other renewables, and quickly evolving technologically.
This means that many of the most advanced startups in the sector are still privately listed. For example, closed-loop geothermal energy Eavor, supercritical geothermy Quaise, or funds only accessible to accredited investors like Baseload Capital.
This also means that some advanced geothermal companies, like Iceland Drilling, might be just a small part of a much larger oil & gas drilling company (Archer Wells – ARCH.OL in this case).
Still, some companies are publicly listed and available to retail investors. You can invest in geothermy-related companies through many brokers, and you can find our recommendations for the best brokers on this website in the USA, Canada, Australia, the UK, and many other countries.
If you are not interested in picking specific space-related companies, you can also look into ETFs like the Shares Global Clean Energy ETF (ICLN), the First Trust NASDAQ Clean Edge Green Energy Index Fund (QCLN), or the ALPS Clean Energy ETF (ACES) to capitalize on the growth of the geothermal energy sector.
Geothermal Companies
1. Ormat Technologies, Inc.
Ormat is the world’s 2nd largest geothermal owner and operator and the largest publicly traded. The company has assets in the US, Kenya, Indonesia, and Central America + the Caribbean, with a capacity of 1.23 GW and 125 MW in development.
Ormat Technologies, Inc. (ORA -0.54%)
Ormat is also entering the energy storage market, with 190 MW online. The company aims to reach a capacity of 1 GW by 2028.
The company is targeting a strong growth of power production capacity, notably with projects in New Zealand and Indonesia.
It is also a provider of geothermal technology, with 3.4GW of geothermal installed over the years, making it the 3rd largest provider of geothermal plants, behind Fuji Electric and Toshiba.
The Inflation Reduction Act supports Ormat’s aggressive growth targets, which should provide up to $125M in cash proceeds annually from tax benefits.
Geothermal energy is currently a quickly growing sector, but also one that is still very conservative due to the lack of familiarity with the technology for most utilities and industrial companies.
In that respect, this makes Ormat well positioned to capitalize on the growing demand, while also being one of the most established players in the industry.
2. Vulcan Energy (VUL.AX)
Vulcan is a German company targeting geothermal energy production in the Rhine Valley while also extracting lithium from the geothermal brine.
The project targets the production of renewable heat for 1 million people, enough lithium for 1 million EVs per year, and 1 million tons of CO2 emission avoided per year.
The heat production matches well the local market, with Germany rich in district heating systems currently relying on coal or gas.
Phase one of the project should result in 275 GWh of power and up to 560 GWh of heat per year.
The company has yet to produce lithium but has already secured off-take agreements with Stellantis, Volkswagen, LG, Umicore, and Renault. This is also reflected in the ownership, with Stellantis owning 6% of the company through a $50M investment.
The lithium resource is expected to decline very slowly, with less than 50% dilution even by 2055. Production should start at the end of 2025. It should also have one of the lowest lithium production costs in the world, beating all the mined lithium and almost all the brine-sourced lithium.
Vulcan is a more speculative project, with no significant cash flow expected before 2026. Still, the first lithium production in 2024 demonstrates the project’s viability, and the prospect of low extraction costs going hand-in-hand with geothermal power generation is interesting.
This could also reduce the carbon footprint for EU-made EVs, as currently, most lithium is extracted using fossil-fuel-powered engines and facilities running at least partially on fossil fuels, making Vulcan the only CO2-neutral, zero-fossil fuel lithium project in the world. It is also the largest lithium resource in Europe.