Central Washington University (CWU) is harnessing geothermal technology to meet our goals of reducing campus-wide greenhouse gas emissions by 45% by 2030 and becoming a net-zero carbon campus no later than 2050. Construction is currently underway for CWU’s GeoEco Center and North Academic Complex (NAC), which will replace two energy-inefficient academic buildings constructed in the 1970s.

The GeoEco Center will utilize an open-loop ground source heat pump system to provide heating and cooling for a half-million square feet of built infrastructure on campus, including the NAC. The geothermal plant is expected to be in operation by early 2026 and will serve as a catalyst for CWU’s efforts to decarbonize its district energy system over the next 15 years. CWU’s first GeoEco Center, along with the demolition of two aging and energy-inefficient buildings, will lead to a reduction of 33,000 metric tons of carbon emissions over the course of 50 years.

Approximately 60% of CWU’s greenhouse gas emissions can be attributed to using natural gas for heating buildings across campus. CWU owns and manages a district energy system (also referred to as a central plant), consisting of three water-cooled chillers and four steam hot water boilers that provide the majority of the heating and cooling for campus buildings. CWU is committed to investing in forward-thinking geothermal technology to effectively decarbonize its heating and cooling infrastructure.

The equipment for the geothermal system will include an injection well, extraction well, a six-pipe heat pump, and a groundwater heat exchanger, which will help ensure there is no groundwater contamination. The groundwater will not be consumed and will only serve as an energy exchanger. The extraction well will pull groundwater from the Ellensburg aquifer (800-1,000 feet below the Earth's surface) and the injection well will reintroduce the groundwater to the aquifer.

The GeoEco Center will also have a solar array and an educational dashboard for students, faculty, staff, and community members interested in learning more about the function and mechanics of the geothermal system. An added benefit is that CWU’s GeoEco Center will serve as a model for other institutions and agencies seeking to decarbonize their district energy systems. 

CWU received additional funding from the Washington State Legislature earlier this year to install and construct a second geothermal injection and extraction well, but these funds are contingent upon the state’s Climate Commitment Act (CCA) surviving a potential repeal during the November election. If the CCA is repealed, CWU will lose the funding for a second geothermal plant and experience significant barriers to achieving its greenhouse gas reduction goals. 

For more details regarding the mechanics of CWU’s Geo-Eco Center, check out the presentation from  Anthony Schoen, Principal, Mechanical Systems at MW Engineers. To read more about CWU’s goals and strategies to decarbonize its campus, please read CWU’s Climate Action Plan, which was completed in early 2024. For questions or additional information, please contact CWU Sustainability Officer Jeff Bousson or Director of Capital Planning and Projects Delano Palmer.

It is extraordinary to think that just beneath our feet there’s enough energy to meet all the world’s energy needs. It is an abundant resource that can be harnessed for human use. Geothermal is a clean and renewable energy source that remains underutilized despite it being a mature and proven resource. Geothermal is the most environmentally friendly energy technology, has the ability to decarbonize heating and cooling of buildings and industry, and can generate dispatchable and baseload electricity all from ample and local geothermal resources. Geothermal presents a compelling case for widespread adoption, and it must become one of the leading protagonists if we are to genuinely address the ongoing climate crisis and successfully transform into a clean energy economy.

The primary energy associated with geothermal is the heat energy that naturally exists beneath the Earth's surface! There are different ways to use the natural heat of the earth. Geothermal heat pumps (also known as ground source) utilize temperatures about two meters below the ground to heat AND cool buildings. Other geothermal technologies use heat energy several kilometres below that is at very high temperatures and is produced by the natural decay of materials within the Earth's crust. Importantly, geothermal energy is constantly replenished, therefore renewable!

Deep within the earth is the hottest part of our planet, the core, which is about 2,900 kilometres below our feet. The extremely high temperature of the core (5,200°C or 9,392°F) serves as limitless battery, recharging the heat beneath our feet that can be used to create geothermal heating, cooling, and power capabilities.

Here are some of the advantages of geothermal:

1. Geothermal is always available: Like other renewable energy sources, geothermal is essentially unlimited, but unlike intermittent renewables it is not affected by season, climate or weather conditions. This is referred to a having high capacity factor of which geothermal has the highest of all renewable energy sources making geothermal a more stable, reliable, and consistent technology. Energy generated from this resource is easy to predict with a high degree of accuracy as it doesn’t fluctuate in the same way as other renewable energy sources, such as solar, hydro, and wind. Geothermal energy is both renewable and sustainable due to the hot reservoirs within the earth being continually and naturally replenished.
2. Geothermal energy plants have a small footprint: Geothermal power plants as well as heating and cooling systems only require modest amounts of space, in contrast with the wide-ranging expanses of land and mining operations needed for intermittent, oil and gas, nuclear and coal energy. Whether it’s a domestic geothermal heat pump system or a large-scale geothermal power plant, most of the components, including the heat exchangers, are buried underground with very little remaining above ground. In homes, a geothermal heat pump is about the size of a household appliance while in geothermal power plants the largest components are the cooling towers and the turbines. Large geothermal power plants can have a visual impact on the landscape, but these days newer architectural designs minimize the visual impact on the landscape.
3. Geothermal energy provides more energy: Aside from time for maintenance, geothermal energy can work at full capacity non-stop because delivery is constant. This is very different to photovoltaic, hydroelectric and wind systems which rarely work at full capacity due to technical and environmental limitations. This means that more power is generated using less land and for the same nominal power. For example, a 9 MW geothermal plant will on average generate energy for about 5,500 homes a year whereas the average 9 MW solar plant can power only 1,800 homes per year. This translates into a lower impact on the environment, less mining for critical minerals, and reduced risk of geopolitical conflict.
4. Geothermal power plants are quiet: While working at full capacity, geothermal power plants run at negligible noise levels. As with all construction, during the building phase of the plants there will be some noise but once the construction is complete, everything runs quietly. This applies to not only geothermal heat pump systems but to larger power stations where several turbines are spinning.
5. Geothermal energy is environmentally friendly: The carbon impact of a geothermal power plant is very low. According to the National Renewable Energy Laboratory, geothermal has the smallest lifecycle carbon footprint of all renewable energy technologies, including wind and solar. Geothermal power generation produces little—if any—nitrous oxide, methane, or sulphur dioxide in contrast with other generation technologies. Binary-cycle geothermal plants, which operate in a closed cycle, release essentially zero emissions, according to the U.S. Department of Energy Geothermal Technologies Office. By utilising the earth’s natural heat, geothermal energy significantly decreases our carbon footprint contributing to cleaner air and a healthier planet.
6. Geothermal power optimises resources: Geothermal plants have components that can be salvaged and reused at the end of the installation’s lifecycle. Furthermore, during operation, the flows of energy are optimized in such a way as utilize any heat that can’t be used immediately for power generation back into the circuit using the steam pipes that power the plant, leading to greater energy efficiency. Geothermal does not require any critical minerals and all materials needed (steel and cement) are easily sourced from North America.
7. Geothermal plants are long-lasting, safe, and reliable: Geothermal heat pumps have an operating life span of over 20 years whereas a traditional furnace last just 7 to 10 years. Geothermal power plants have very long life spans, with some lasting up to 80 and even over 100 years. Geothermal power plants such as Lardarello in Italy (1913), Wairakei in New Zealand (1958), and The Geysers in California (1960) still use original operational infrastructure and wells. This is remarkable longevity when compared to a natural gas combined-cycle plant which normally lasts around 30 years. Because there are no fuels involved there is no risk of fire and overall, this type of system guarantees excellent reliability. Additionally, geothermal power plants have low operating costs once the initial infrastructure is in place making them economically competitive in the long run.
8. Geothermal plants require very little maintenance: Especially when it comes to geothermal heat pumps, geothermal applications don’t need any special maintenance. Because geothermal heat pumps are closed systems, the pressure of the fluid in the piping self-regulates and the number of electrical and mechanical elements that can break down is also minimal.
9. Geothermal can be used to both heat and cool: Geothermal systems can be installed in almost any type of building: from homes to shopping malls, public buildings, and sports centres. A geothermal heat pump is actually a two-in-one HVAC system used for both heating and cooling. Despite the misleading name, geothermal “heat pumps” are just as effective at cooling your home or office in the summer as they are at heating it in the winter!
10. Geothermal heat pumps can reduce overall energy consumption in your home: As well as providing air conditioning in the summer and heating in the winter, geothermal has other advantages when used in the home. For example, it can reduce energy consumption by between 30% and 70% because it can also do the job of a boiler by heating water for use in the kitchen and bathroom.
11. Geothermal improves public health: Traditional air-conditioning removes dangerous heat from buildings and provides life-saving shelter and comfort. Unfortunately, air-conditioning systems worsen two other problems. First, heat is not so much removed or eliminated as it is moved from one location to another. When a building interior is cooled, that thermal energy is transferred to the exterior surroundings. In dense urban areas, this effect increases local temperatures, exacerbating the heat wave in places that are already heat islands as a result of urbanization. A geothermal heating and cooling system can reduce building interior temperatures without heating the surrounding air space by storing and dissipating heat underground. Additionally, geothermal heat pumps are 40% more efficient than their air-source counterparts, especially at high and low temperatures. 
12. Geothermal energy creates record numbers of jobs: Geothermal creates more jobs per megawatt hour than all other renewable energy technologies, according to the National Renewable Energy Laboratory. For the same installed power, geothermal energy creates more direct and indirect employment than any other type of renewable. Geothermal creates 34 jobs per installed megawatt compared to 19 created by wind power and 12 by photovoltaic energy.
13. Geothermal pays local communities: Over the course of 30 to 50 years an average 20 MW geothermal generation facility will pay nearly $6.3 to $11 million dollars in property taxes plus $12 to $22 million in annual royalties. Seventy-five percent of these royalties ($9.2 to $16.6M) go directly back to the state and county.
14. Geothermal energy can improve energy independence and security: Geothermal energy can contribute to enhancing a nation's energy independence and security. By utilising domestic and locally sourced geothermal resources, countries can reduce their dependence on imported fossil fuels and critical minerals, minimizing geopolitical risks associated with energy supply chains. Developing geothermal projects can strengthen a nation's energy portfolio and provide a stable and secure source of energy for future generations.
15. Geothermal energy has huge potential: Currently, worldwide energy consumption from geothermal resources is around 15 terawatts but the total potential energy from geothermal sources is far greater. While most of the geothermal potential is still yet untapped, there is robust research and development happening in the industry that will increase the number of recoverable geothermal resources in the future. It is estimated that new technologies to create Engineered, or Enhanced Geothermal Systems (EGS), can add 100 gigawatts of geothermal power to the grid (Office of Energy Efficiency & Renewable Energy). The 2019 GeoVision analysis concluded that, with advancements in EGS, geothermal could power more than 40 million U.S. homes by 2050 and provide heating and cooling solutions nationwide. Advancements in closed-loop or Advanced Geothermal Systems (AGS) will unlock even more opportunity for geothermal. Additionally, super-hot rock (SHR) technologies have the potential to generate terawatts of power.
16. Geothermal energy use is rapidly evolving: There is growing interest and new research into geothermal innovations. New technologies, such as refined heat pumps, EGS, closed loop systems (AGS), SHR, improved drilling techniques, and more efficient turbines, are being created all the time to improve the energy process. There are an ever-increasing number of projects to improve and grow this area of industry. Within the last few years there have been over 40 geothermal energy start-ups founded in North America.

Geothermal energy has numerous advantages that make it an ideal option for a sustainable transformation to a healthier, more equitable, vibrant economy. With its renewable and clean nature, consistent availability, long-term viability, and versatile applications, geothermal energy offers a path towards a greener and more resilient and stable energy future. By embracing this remarkable resource, we can reduce our carbon footprint, combat climate change, and ensure a more sustainable and just planet for generations to come.

To learn more about harnessing the power of geothermal energy, contact Geothermal Rising, a community that advocates for the growth and deployment of geothermal energy. Founded in 1972, Geothermal Rising is a community of geologists, climate activists, oil and gas professionals, drill rig operators, environmentalists, geochemists, subsurface reservoir modelers and more. Geothermal Rising represents and speaks for an aligned geothermal industry. The non-profit is a renewable energy think tank designed to familiarize and inform audiences about the value and benefits of geothermal energy for heating and cooling as well as electricity generation. Please visit www.geothermal.org.

To learn more about renewable energy technology and how they can be deployed please visit: https://www.renewableenergyhub.co.uk/

There are three types of geothermal energy:
•    Geothermal power plants that produce electricity
•    Direct use and direct heating systems
•    Geothermal heat pumps
Let’s explore each of these exciting natural possibilities. Why? So, we can use the earth to save the earth.

Across the United States and around the world, there are reservoirs of hot water. This water can be found near the earth’s surface, or deeper down. The water is extremely hot, with temperatures ranging from 300° to 700°F. Geothermal power plants use the steam from the hot water to produce electricity.

It’s a simple process. The steam creates energy that rotates a turbine. The turbine activates a generator and electricity is produced. And this is a natural resource, so we’re using these reservoirs in the earth to power the earth.

Geothermal power plants are built where the reservoirs of hot water are located. In the U.S., most of the reservoirs are in the western states, but there are also reservoirs in the South, Midwest, and East Coast. This means that we can be using this natural resource more than we are currently.

And scientists and engineers are working on innovative technologies that will allow geothermal power plants to be built anywhere around the world, serving clean and renewable electricity at any time!

There’s another kind of geothermal energy that’s readily available called geothermal direct heat. It’s a simple process: direct heat comes from the water found in rock beneath the earth’s surface. The hot water in the rock reservoirs produces heat and steam, but isn’t hot enough to be economical to generate electricity. This water is captured and piped into buildings to provide heat, melt ice on roads and sidewalks, and warm fishing farms, greenhouses, and swimming pools.

Direct heat systems are already in use all around the world to make our lives better. For example, direct heat systems provide heat for most of the buildings in Reykjavik, Iceland. Direct heat is also used for food dehydration, pasteurizing milk, and mining gold. It’s an easily accessible and effective geothermal energy source.             

Finally, there are geothermal heat pumps. These heat pumps work by using the heat that naturally occurs in the ground. Did you know that temperatures in the earth 10 feet below ground range from 50°F to 60°F. This means that soil temperatures are typically warmer in the winter and cooler in the summer than the air. Geothermal heat pumps use the earth’s temperature to heat and cool buildings. How? During the winter, heat pumps take the heat from the ground into buildings. The process is and reversed during the summer.

According to the U.S. Environmental Protection Agency (EPA), “geothermal heat pumps are the most energy-efficient, environmentally clean, and cost-effective systems for heating and cooling buildings. All types of buildings, including homes, office buildings, schools, and hospitals, can use geothermal heat pumps.” In addition to heating and cooling buildings, geothermal heat pumps can provide hot water. Best of all, this is clean, renewable energy.

As demand for energy increases, geothermal energy will become an increasingly important energy source.  Right now, California has 43 operating geothermal generating plants, and plans to build more. A 2019 U.S. Department of Energy (DOE) report, GeoVision: Harnessing the Heat Beneath Our Feet, says, “generating electricity through geothermal methods could increase 26-fold by 2050, providing 8.5 percent of the United States’ electricity, as well as direct heat.” And, in Boise, Idaho, geothermal energy is heating 92 of biggest buildings in the city.

Let’s all embrace geothermal energy: a clean, green, renewable energy that uses the earth to power the earth.

https://www.eia.gov/energyexplained/geothermal/geothermal-heat-pumps.php

https://www.eia.gov/energyexplained/geothermal/use-of-geothermal-energy.php

https://www.go-gba.org/resources/green-building-methods/geothermal-energy/

https://www.energy.gov/eere/geothermal/electricity-generation

https://e360.yale.edu/features/can-geothermal-power-play-a-key-role-in-the-energy-transition

https://www.energy.gov/eere/geothermal/downloads/geovision-harnessing-heat-beneath-our-feet