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WarOnPrivacy
wood_spirit
In the nordics it is common to have ground source heat pumps (brine in closed circuit pipe or bore hole) that are run backwards in summer to cool the house while actually assisting in storing heat back in the ground to extract in the winter. It’s a bit like regenerative breaking on electric cars.
ninalanyon
No it's not. It exists but it's certainly not common for individual dwelling to use ground source heat pumps, at least in Norway. It is more common in Sweden[1] but still far less common than air source and over 90% of heat pump installations in Norway are air source[2].
The only ground source installations I can think of in Norway serve large office buildings and similar. The largest heat pump installation I know of in Norway is actually a third kind: water source[3]. It takes heat from the Drammen river to provide heat for a district heating system and for keeping the town centre clear of ice in the winter as well as supplying the new hospital with heat.
I imagine that the rest of the Nordic region is similar.
See:
[1] http://publications.jrc.ec.europa.eu/repository/bitstream/JR...
[2] https://www.sciencedirect.com/science/article/pii/S221313882...
[3] https://energiteknikk.net/2023/11/drammen-fjernvarme-storst-...
sumea
If by Nordics you mean Norway, Sweden and Finland, then the most correct way to say would be that ground source heat pumps for redidential heating are (very) common in Sweden and Finland, especially in newer and larger buildings. Norway is somewhat different in energy and climate perspective than its eastern neighbours.
The biggest reason to not install ground source heat pump is high installation cost. This means that it makes more sense for larger residential buildings. Also If you have district heating available then this might be more economical in the long run.
deliciousturkey
In Finland around 50% of new single-family homes use ground source heat pumps. So it's definitely popular here.
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emil-lp
3 schools in my neighborhood (barneskole, ungdomsskole & videregående) all use ground source heat pumps.
jjtheblunt
There was a new in 1988 house in Champaign, Illinois, USA that used the same system, and i mention that because it was a normal modern house, and it's the only one i've heard of with that system.
It seems so smart.
maxerickson
It's expensive. A relative has one in the northern Great Lakes, they wouldn't have installed it if their house had access to natural gas.
zdragnar
There's a pretty significant upfront cost in getting them drilled, and many homes need the vertical drilling if they don't have sufficient yard space for a horizontal system. It gets harder if you have your own septic drain field too, as that will complete for yard space.
The cost difference is pretty massive- 3-10x for a vertical system. If you live in a city or a suburb with tiny lots, that's your only option though.
Nat gas and central AC are way cheaper.
Animats
Shallow geothermal works fine for heating. And you can use the ground as a heat sink. But if you want to generate power, you need to get down to where temperatures can boil water. That's deeper than most oil wells. Fervo Energy claims to have found 270C at 3350 meters well depth. That's progress.
lostlogin
> if you want to generate power, you need to get down to where temperatures can boil water. That's deeper than most oil wells.
That’s going to be very dependant on location.
Here in NZ there are regions where water is boiling at surface level.
According to the below, 18% of our power is produced with it.
https://www.eeca.govt.nz/insights/energy-in-new-zealand/rene...
Animats
"New Zealand has an abundant supply of geothermal energy because we are located on the boundary between two tectonic plates. ... Total geothermal electricity capacity in New Zealand stands at over 900 MW, making us the fifth largest generator of geothermal in the world. It has been estimated that there is sufficient geothermal resource for another 1,000 MW of electricity generation."
That's not all that much. That total would be about equal to the 75th largest nuclear plant in the world.
Good sites where high temperatures are near the surface are rare. California has a few, but no promising locations for more.
thinkcontext
You brought the conversation in a circle, since the point of this new technology is the geology you speak of is rare.
dboreham
There are also places in the US with boiling water at the surface. I live near one of those places so always curious about geothermal. There's a spot near my house in a creek bed where snow always melts even in deep winter so apparently I have some potential heat source. Our well water is cold though.
bialpio
> But if you want to generate power, you need to get down to where temperatures can boil water.
Why is that the case? Can't you go down to where it's like 70-80 deg C and close the gap using heat pumps? Yes, you need to put some energy in, but I would expect that the whole process would still be energy-positive at some temperature that's lower than 100C?
quijoteuniv
I think this looks interesting, but still very early stage. The “150 GW revolution” sounds more like theoretical potential, not something we will see soon in real deployment.
Main problems: drilling is still expensive, managing induced seismic activity is not trivial, permitting can take long time, and you also need transmission infrastructure. Also not yet proven that companies like Fervo can scale this in reliable and low-cost way.
jeffbee
Nope. To efficiently tap geothermal energy, you need to boil something but not necessarily water. Isopentane, for example, boils at 28º at standard pressure, so they pressurize the secondary loop to raise the boiling point close to whatever the primary loop temperature is.
The idea that geothermal only works well at steam temperatures is outdated 20th-century thinking.
emmelaich
But the energy in boiling isopentane would be less right?
acdha
> I always thought this method could be used to provide a/c for neighborhoods, operated as a neighborhood utility. I've not seen it done tho. I've seen neighborhood owned water supplies and sewer systems; it tells me the ownership part seems feasible.
I keep thinking this would be a great municipal code change: any time the roads are being built or ripped up for water/sewer maintenance, put in a ground loop and subsidize household connections for heat pumps so instead of having to deal with the marginal difference between 20℉ winter air you'd be working with 50-60℉ ground temperatures.
solarpunk
I think you're describing what is known as "district energy" systems.
mlwiese
Framingham, MA has a geothermal system using ground source heat pumps like what you are describing
https://www.smartcitiesdive.com/news/first-networked-geother...
limagnolia
Whisper Valley in Austin Texas is one example of a neighborhood geothermal installation: https://www.canarymedia.com/articles/geothermal/texas-whispe...
Maybe not quite exactly what you envision.
WarOnPrivacy
> Maybe not quite exactly what you envision.
I'm too zonked to pick out the method from the article - but I'll offer that geo methods can be region specific. What I described fits the SE US, with our 13 month summers and abundant underground water.
limagnolia
13 month summers lol :) Yeah, definitely if your interested neighborhood geothermal Whisper Valley seems to be the largest by far in the US, you might check it out.
wesapien
One of the problems with the data center boom is its use of fresh water. How does geo-thermal plants use water and how much?
micro2588
The water at these temperature / depths has a lot of dissolved salts and minerals so it's not (human / ag) usable. Modern designs are closed loop systems where production wells bringing the hot water to the surface go through a heat exchanger to a different working fluid to drive the turbine and then is re-injected back into the reservoir. There is consumptive water use for fracking the reservoirs in these types of enhanced geothermal systems, but beyond that it's more water redistribution in the area around the well systems where re-injection and production lead to different pressurization from pumping / natural ground water replenishment rates.
WarOnPrivacy
> The water at these temperature / depths has a lot of dissolved salts and minerals so it's not (human / ag) usable.
To clarify, our 400' water source is the same aquifer that supplies drinking water to the state.
The water management districts will rubber-stamp permits for these wells. No one else gets off that easy.
ksec
I dont know why this keeps coming up? It is a closed loop system. The water aren't used at all.
WarOnPrivacy
> It is a closed loop system. The water aren't used at all.
Our method is open on both ends. It draws from one layer of the aquifer and then returns the water to an adjacent layer.
msandford
It's a closed loop on the geo side sure.
How do you cool the steam off enough to condense so it can go and be boiler feed water again?
Lots of power plants use cooling towers for this which are typically evaporative. Some are dry, sure, but most are wet.
justnoise
Many data centers use evaporative cooling.
WarOnPrivacy
> One of the problems with the data center boom is its use of fresh water. How does geo-thermal plants use water and how much?
Baring leaks, ground source heat pump geo will consume no water at all. Water is pumped from one layer of the aquifer and is returned to a slightly higher layer.
quickthrowman
District heating and chilled water is uneconomical for single-family homes. It does work well in medium to high density areas.
gambiting
I don't know how economical that is, but just as an anecdote - the town I'm from in Poland has district heating to all single family homes, town of about 20k people. And coincidentally, I now live in the UK and a new estate near me has district heating to all the houses they are building, not apartment blocks. So it must make some sense to someone, or they wouldn't be outfitting 100+ houses this way.
quickthrowman
It’s uneconomical in an already built out area or a non central planned economy, and also the US is special case since we have dirt cheap natural gas that is used for heating.
Digging up streets to run distribution lines, running service drops to every existing house, installing a heat exchanger and valves in every house is astronomically expensive given the amount of energy used by a single residence.
If you’re building out a new neighborhood on a greenspace plot, installing the district heating/cooling piping is much cheaper since you’re already laying electric, water, sewer, and mane gas lines.
mschuster91
At least in parts of Eastern Europe (especially the former GDR) district heating systems were introduced as a response to the oil crises of the 70s, resulting price shocks and the transport of coal to households being very labor and resource incentive [1].
[1] https://www.ndr.de/geschichte/schauplaetze/Windkraft-und-Erd...
hunterpayne
"I don't know how economical that is"
Sure you do. Think about it. Its just drilling a hole and making electricity from the heat. We have been able to do this for a very long time. So if people aren't really doing it much, its not economical. If it was now becoming economical, the article would describe some new way of doing it that makes it economical. The article doesn't, so you "know" it isn't.
PS This has been tried many time, it only works in very specific situations, usually places where building a full PP doesn't make sense or where you are making a lot of electricity for some other purpose (mining usually).
Animats
Oh, Fervo Energy again. They're trying to IPO, hence the hype. Wikipedia's warning: This article reads like a press release or a news article and may be largely based on routine coverage. (February 2026) This article may have been created or edited in return for undisclosed payments, a violation of Wikipedia's terms of use. It may require cleanup to comply with Wikipedia's content policies, particularly neutral point of view.
Here's a more realistic evaluation of Fervo.[1]
[1] https://www.latitudemedia.com/news/what-fervos-approach-says...
tptacek
That's Wikipedia warning about the quality of the Wikipedia page, not about the company.
w1
This isn’t really an evaluation of the company, just explaining how they had to use different financing approaches as they grew and derisked their technology (which makes sense).
Compared to some other new approaches for getting clean base load power, it seems like they’ve been pretty grounded and methodical.
Animats
They're way ahead of the microwave drilling people.
There's no reason why this shouldn't work. But they've been at it for 9 years, with considerable funding, and it doesn't really work yet. That's a concern.
mgfist
> There's no reason why this shouldn't work. But they've been at it for 9 years, with considerable funding, and it doesn't really work yet. That's a concern.
It does work. They've had a pilot project producing 3 megawatts since 2023. But scaling takes a lot of time and money, particularly when it's something new and you have to go through a lot of operational learning.
Shale took something like 30 years to become a thing. 9 years is nothing in the energy space.
hunterpayne
"There's no reason why this shouldn't work."
Geothermal has had the same problem for its entire history. That problem is that the water being heated goes through the ground (not in a pipe) to "gather" more energy. But this means that when the water comes back up, it has a lot of weird salts in it (and other things). Those salts cause corrosion, lots and lots of corrosion, far more than even a maritime environment. So the plant needs to be shutdown a lot of the time for repairs. And that's what makes it uneconomical. Also, the salts often contain things that require special handling which also increases costs.
PS This is why geothermal works in Iceland where there is so much geothermal heat they can use pipes. In CA, they can't so it doesn't work there.
RITESH1985
I work in nuclear sector and if geothermal power works, its better to use. Given the huge timeline we have for our projects, the regulatory nooks and the large initial capital requirements, geothermal could be a solution, though not the only one to rely on. The basic economics metric for any generating plant is the levelized cost of electricity (LCOE), the total cost to build and operate a power plant over its lifetime divided by the total electricity output dispatched from the plant over that period. This again is lower for geothermal as compared to nuclear.
pedalpete
According to google, this would be almost 30% of total US energy production (135gw-150gw) and nearly 5% of total US energy consumption.
But what is the "breakthrough" if there is one? The article doesn't really suggest any breakthrough that is unlocking this potential energy? Or maybe I'm looking for a technological breakthrough where there isn't one.
hunterpayne
There isn't one. They are trying to politically pressure a utility to build some geothermal plant. But utilities have engineers who will tell their bosses that this plan doesn't work. So the companies selling the geothermal plant are trying to politically pressure the utility to do yet another thing that they know won't work. PG&E for example has several geothermal plants which have been economic disasters and were and are being shutdown.
micro2588
The core breakthroughs were working with partners to develop PDC bits that enable high rates of penetration in drilling out these horizontal wells in high temp granitic rock and then demonstrating plug / perf fracture networks that have a high engineered permeability in these source rocks to support economical flow rates and heat transfer. These were considerable advances over previous efforts.
There will be other learning by doing advances in how you structure your power plant design to take advantage of these to make practical long term power production possible (well spacing and injection / production placement / flow rate and temperature decline management).
mgfist
> PG&E for example has several geothermal plants which have been economic disasters and were and are being shutdown.
Those are very different from EGS
floatrock
They're adapting fracking techniques to use for geothermal, which opens up many more sites. Historically geothermal has had limited potential, and the best sites have already been developed. So geothermal + fracking creates a lot more viable land.
Traditional geothermal is you dig a really deep well and get a geyser of hot water or steam to come up.
Fervo is doing "Enhanced" or "Engineered" geothermal where you dig two wells: an injection and an extraction well. You frack the rock in between, creating lots of small channels for water to flow between them. The water absorbs the heat from the rocks as its circulating from the injection well to the extraction well.
The kind of rock that's good at this heat transfer is different from shale rock that oil & gas frackers have experience with... it's harder, less porous, not partial-dino-juice. So they're taking a lot of the same core concepts from the oil & gas industry (horizontal drilling, geology simulations, etc), but their IP is in adopting the techniques to work with geothermal-favorable rock.
Another interesting concept I heard Fervo researching: this kind of geothermal is not "baseload" style power, so there's a few tricks they can do to get better cost efficiency and peaker-like or battery-like behavior. Remember the two wells that form the circulation loop: injection and extraction? Well, you need pumps on both sides (remember, this isn't "geyser-style" geothermal where natural pressure and geology do all the work). Pumps take energy to run, something like 20-30% of the overall extraction output (you put a unit of energy in to run the pumps and you get 3-5 units of energy back out the other end). Not great, not terrible either... it's an energy return comparable to solar and wind. But what you can do is run the injection pump when power prices are low (ie when there's an excess of solar on the grid), pressurize all your fracked channels underground (the reservoir), and then when grid prices rise in the evening you run just the extraction pump to pull out the pre-heated, pre-pressurized water. You're still at a 3-5x energy return, but the time-shifting has made the cost multiplier more favorable.
My understanding is it's still in research phase, but Fervo is piloting this technique. Like another thread said, they're pre-IPO now, so they've been flooding the renewables media with all these stories. They filed an S-1 recently, but always read the eventual S-3 before considering your investment options blahblahblah.
hn_throwaway_99
4th paragraph of TFA:
> Several companies are now building upon existing techniques for accessing geothermal resources by integrating enhanced geothermal systems (EGS) into operations. While conventional geothermal systems produce energy using hot water or steam, pumped from naturally occurring hydrothermal reservoirs trapped in rock formations underground, EGS use innovative drilling technologies, such as those used in fracking operations, to drill horizontally and create hydrothermal reservoirs where they don’t currently exist.
nandomrumber
Sounds like marketing hype to me.
Geothermal reservoirs exist at depth.
Drilling horizontally doesn’t magically reduce the depth, nor the problem that drilling in to hot rock is like drilling in to plasticine, at least for temperatures worth working with.
micro2588
In traditional fault hosted (not magmatic) geothermal the convection of the water up the fault brings the thermal energy closer to the surface where drilling depths are economical. This convection heats the surrounding rock and over hundred thousand - million of years brings the background temperature around a large volume at depth surrounding these systems considerably above traditional background geothermal gradients. By drilling into a much larger volume of impermeable hot rock surrounding a very small permeable fault hosted section you can considerably enhance the power potential of a traditional fault hosted geothermal system (the E in EGS). That is what Fervo is doing and why their projects are situated right next to traditional geothermal power plants.
The assumption is that if you can increase drilling efficiencies enough then you don't even need a fault hosted or similar system to bring that energy close to the surface, you can just drill down deep enough to get at similar temperatures. That is a big assumption in the economics.
sunshinesnacks
EGS has been around for at least 15 years. See AltaRock Energy as an example (I’m sure there are others). They started almost 20 years ago. https://en.wikipedia.org/wiki/AltaRock_Energy
nusl
So it basically says nothing useful other than try to generate hype and make them look good.
thinkcontext
No. Current geothermal projects need very specific geology to work, its very rare which is why geothermal is such a small blip in the overall energy picture. Enhanced Geothermal Systems (EGS), the technique Fervo is using, can create the conditions to be able to generate electricity. The hope is this will greatly expand the number of projects that can be developed.
Doesn't that sound useful to you?
skybrian
My understanding is that it's due to better drilling techniques. The industry learned a fair bit from fracking and they're learning more from experience as they apply it to geothermal.
No particular breakthrough, but there's a learning curve and they learn more as they do more. Other industries sometimes work that way, too.
https://www.austinvernon.site/blog/geothermalupdate2026.html
dyauspitr
It’s a stupid ploy by oil drillers to try and expand their existing capex to something more future proof. Their theory is to randomly frack the ground and hope superheated water shows up there. It’s probably just going to end up ruining existing groundwater sources.
mcoliver
The Casa Diablo geothermal facility in the eastern Sierra Nevada of California has been a success. I also remember reading years back about ideas surrounding how to extract energy from Yellowstone both to provide clean energy but also to decrease risk of another massive explosion. If I recall they were proposing digging a massive horizontal tunnel to come in deep and extract heat without compromising the roof.
Long Valley Caldera Geothermal Area | Open Energy Information https://share.google/5DvljMhL3EVMDeIAL
Aboutplants
While I’m not extremely bullish on large scale geothermal, much like with Housing, we need any and all types of it.
Melatonic
Those geothermal plants up by Mammoth Lakes are looking like a great idea right now
jmward01
Here is an article that is a bit old but discusses the start of things [1]. It would be a bit ironic if fracking tech helped get us further from using natural gas. I think the reality will be if this gets established we will see rapid improvement as scale comes on line so if it is remotely economical now it will be massively better in 5-10 years. Of course the 'if' applies.
[1] (2023) https://time.com/6302342/fervo-fracking-technology-geotherma...
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m0llusk
With all the exotic drilling tech making fracking work, it seems like geothermal is a natural pivot since much of the challenge is controlling the cost of drilling deeply.
runicelf
Would be great to see this in our lifetime
idontwantthis
Is 150GW enough for a “revolution”? That’s about 10% of current total power production.
edbaskerville
Solar and wind, with battery storage, can get you to say 90%, and then you only need 10% from other sources like geothermal and nuclear to fully decarbonize.
smallerize
Solar is at 7%. It's very significant.
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I worked on geothermal control systems a decade or so back. There are some less obvious applications for geothermal that reduce electric use (as opposed to generating electricity).
The systems I worked on were for cooling larger structures like commercial greenhouses, gov installations and mansions. 64° degree water would be pumped up from 400' down, run thru a series of chillers (for a/c) and then returned underground - about 20° or 25° warmer.
I always thought this method could be used to provide a/c for neighborhoods, operated as a neighborhood utility. I've not seen it done tho. I've seen neighborhood owned water supplies and sewer systems; it tells me the ownership part seems feasible.