Baseload generation is useless in 2025. It's in the name; it's called "base load", not "base generation".
Base generation was a cost optimization. Planners noticed that load never dropped below a specific level, and that cheapest power was from a plant designed to run 100% of the time rather than one designed to turn on and off frequently. So they could reduce cost by building a mix of base and peaker generation plants.
In 2025, that's no longer the case. The cheapest power is solar & wind, which produces power intermittently. And the next cheapest power is dispatchable.
To take advantage of this cheap intermittent power, we need a way to provide power when the sun isn't shining and the wind isn't blowing. Which is provided by storage and/or peaker plants.
That's what we need. If added non-dispatchable power to that mix than we're displacing cheap solar/wind with more expensive mix, and still not eliminating the need for further storage/peaker plants.
If non-dispatchable power is significantly cheaper than storage and/or peaker power than it's useful in a modern grid. That's not the case in 2025. The next cheapest power is natural gas, and it's dispatchable. If you restrict to clean options, storage & geographical diversity is cheaper than other options. Batteries for short term storage and pumped hydro for long term storage.
The right answer is 'yes to all the above'. Yes, we need solar. Yes, we need wind. Yes, we need batteries and, yes, we should be looking at geothermal. Solar has shown us, again, how artificially holding back a technology for decades has massive costs. Investing a few billion into geothermal right now is cheap and can only lead to a more durable energy infrastructure in the future. There are all sorts of benefits to a rich ecosystem of power generation. Solar and batteries may be amazing but global supply chains can be disrupted. Similarly, having multiple solutions means that niche use cases have more options and a larger likelihood of finding an acceptable solution. So, yes to all of the above. We are big enough to try them all.
> Solar and batteries may be amazing but global supply chains can be disrupted.
Solar and batteries aren't consumables, so they're not particularly vulnerable to supply chain disruption. If we lose our supply of batteries, we'll have ~10 years or so to find an alternate supply. We won't be able to do new installations during the disruption, but existing installations don't stop working.
Unlike a fossil plant when the supply of fuel is disrupted.
nobody ever seems to recognize the benefits of Modularising your grid as well.
Ukraine is an excellent example of why centralizing your grid energy source is a bad plan... but not just for war situations. If you have an agile, adaptable modular grid you can recover for any form of disaster (natural or man made) very quickly and cheaply.
I really feel this is an under valued aspect of electrification and greening of the power sources we use.
With fossil power plants, the bigger plants were more efficient. This lead to centralization. We now find ourselves in a situation where you can end up with a lot of small/local generation.
What happened in Ukraine can probably happen in almost every developed country today as this was all built/planned in a different time.
yeah I'm not saying that they messed up, I'm saying that we dont appear to be taking note from the situation. Doing better based one the world as it is now and how history has played out.
Caterpillar provides some really neat small scale flywheel UPS - used in places like hospitals where it would be very bad to lose power. They last long enough for the diesel gennies to start up.
From what I saw: In Spain, inverters are not allowed to provide voltage control, and what we saw in Spain, was a voltage spike that caused generators to drop offline, which then caused frequency issues.
Ignore the clickbait headline here: Australia’s Solar Boom Is Breaking the Grid - Or Is It?
It's a sub 15 minute actual grid engineering for lay public explainer video (I know, I'm not a video fan either)
A better duller title might be: How Australia's Grid is being adapted to Solar Boom
00:00 Introduction
01:23 The Problem with Too Much Solar
03:29 Batteries Change the Economics
05:40 What the Grid Actually Needs
07:04 A Cautionary Tale – The 2025 Iberian Blackout
08:21 Australia’s Secret Weapon – Experience with Weak Grids
10:08 The Genius Technical Fix – Grid-Forming Inverters
12:25 The Perfect Partner - Batteries
12:58 From Mechanical to Software-Defined Stability
13:42 Conclusion – Fixing the Grid Before It Breaks
But is it usefully dispatchable? Nuclear can be made dispatchable but it's not usefully dispatchable because the costs are fairly similar whether the plant is on or off.
Like nuclear, I believe geothermal has high capital cost and low running costs, suggesting that it isn't usefully dispatchable.
But that's too simplistic. A big limitation of geothermal is that rock has poor thermal conductivity. So once you remove heat it takes a while for it to warm up again. If you're running it 100% then you need a large area to compensate. OTOH, if you're running it at a lower duty cycle you likely need less area.
So if you know the duty cycle in advance, then you can likely significantly reduce costs. Yay!
But that also means that you likely can't run a plant built for low duty cycles continuously for 2 weeks during a dankelflaute. It's likely great for smoothing out daily cycles, but not as good for smoothing out annual cycles. That means it's competing against batteries, which are also great for smoothing out daily cycles, and are very inexpensive.
> I believe geothermal has high capital cost and low running costs
Higher capital costs, but not nuclear high capital costs.
> That means it's competing against batteries, which are also great for smoothing out daily cycles, and are very inexpensive.
It likely would supplement batteries rather than compete against them. A battery buffer would allow a geothermal plant to slowly rise to load and fall as that load goes away.
A very large battery can store 200MWh worth of energy. The largest geothermal plant produces 1.5GW. (A lot of the large plants look like they are in the range of 100->200MW). Presumably those plants can run for more than a few hours which ultimately decreases the amount of batteries needed to smooth out the demand curve.
Nuclear produces very dangerous substances. The long term cost to guard us from them for a million years and the risk that something gets out of control are extemly high.
That wasn't the conclusion, though. The conclusion was that dispatchable geothermal is competing against daily cycling batteries, a competition it's likely to lose on cost.
You are using long-term in an extremely vague way.
Pumped hydro is not a solution for seasonal storage or yearly storage. Seasonal variation can be a problem in higher latitudes.
For example we have a serious problem in New Zealand where our existing "green" hydro lakes are sometimes low and our economy is affected: creating national power crises during dry years. We use coal-burning Huntley and peakers to somewhat cover occasional low hydro generation.
Unfortunately our existing generators also have regulatory capture, and they prevent generating competition (e.g. new solar farms) through rather dirty tactics (according to the insider I spoke with).
Apparently much of our hydro generation is equivalent to “run-of-river” which requires the river to flow. Although the lakes themselves are large, they don't have enough capacity to cover a dry year.
NZ had planned a pumped hydro, but it was expensive: planned cost of 16 billion compared against total NZ export income of ~100 billion. https://www.rnz.co.nz/news/national/503816/govt-confirms-it-... So completely uneconomic risk (plus other problems like NIMBY).
> Although the lakes themselves are large, they don't have enough capacity to cover a dry year.
It was shocking to me to drive by many of the California lakes/reservoirs that were overfull in the spring of 2019 only to hear that they were basically running dry two years later, and realize that as substantial a water storage system as they are, they're not multi-year scale against the required water supply.
Long term storage is definitely the weak point of moving to 100% carbon free electricity. Unfortunately geothermal does not cover this need. If we want to cover a dankelflaute with geothermal, we basically need enough geothermal to cover ~100% of our power needs. Pumped hydro is the best answer we have at the moment, even if it isn't a great answer.
What will likely happen is that people will decide that "99% is good enough", and use fossil generators to cover dankelflautes,
State subsided construction and maintenance doesn’t pass straight through to consumer prices.
Also, France can’t build new nuclear for cheap/fast anymore either. They have a program for new reactors, even if they go ahead the first one won’t come online till 2038 by the earliest. We can’t wait that long.
The two nukes that recently came on line in the US were so over budget and timeline that all customers now pay a “surcharge” on their bill to pay for it.
Western counties building nukes is so expensive it makes the cost of electricity go up.
France is a western country with its own economic and labour troubles. The enormous expense of building nukes in the US is entirely its own making and much more complicated than just "western" inefficiency.
You might want to look up flammanville. They built a new reactor there and that also took 20 years or so and was way over budget.
We've built a lot of nuclear in the last century and then largely stopped. A lot of the know how is gone which is what we're paying for now.
Also, in France, all those reactors were largely the same leading to economies of scale when building them. Everything we build today is essentially a one of so you don't get to spread that cost over multiple.
Hyper administrative state-capitalist economies all have the same problem with infrastructure. The US has an image of being more capitalist and efficient, which is true to a degree, but once you get a large-scale project that hits all fed->state->municipal politics it's not much different than France. It's just minor variations of who the mandatory 'stakeholders' are ...who demands a cut and who delays/blocks progress.
As soon as some project is being pitched by politicians as "creating thousands of local jobs" it's either DOA or will be many years late and over budget.
Weakly defined. What does "run entirely off renewables" mean?
We know that in North America, for example, significant energy use comes from transportation and heating requirements, and that at this time, very little transportation is powered by renewables, and not a whole lot of heat either (though both are growing).
On the other hand, the entire current residential electrical demand of the city of Santa Fe (about 82k people) can be met with a single relatively small PV+BESS plant (and might just be if it manages to get built).
Suitable locations for pumped hydro are very limited, it is a comparably rare resource.
A lot of mountainous places are dry, and a lot of wet places are flat.
Of the remaining places, some are so unique that they cannot be destroyed by industrial construction (National Parks etc.)
For example, the main ridge of Krkonoše (Riesengebirge) on the Polish-Czech border has a lot of wind and rain and deep valleys, but it is the only place south of Scandinavia with a Scandinavia-like tundra and many endemites surviving from the last Ice Age. Any attempt to construct pumped hydro there would result in a national uproar on both sides of the border.
Pumped hydro just requires a lake at the bottom of a slope. Unlike hydro generation, it doesn't require flow. Here's almost a million locations suitable for pumped hydro: https://re100.eng.anu.edu.au/global/
This "there is no base load" idea is a ridiculous myth trivially disproven: every grid on the planet has continuous demands on it and they're quite significant (5 GW is about 50% the day time peaks).
It doesn't matter what the cost is, because later this evening or tomorrow morning I can guarantee you the same thing: my state will need at least 5GW of power to literally keep the lights on.
> my state will need at least 5GW of power to literally keep the lights on.
I think this abstraction is missing the elasticity of demand that can by unlocked by end-to-end dynamic pricing. Probably if the production was cut in half for some day, and hourly price hiked up until demand matches production, customers would still choose to keep most of the lighting while postponing some more energy intensive loads.
You misunderstand the point though. Sure there is always 5GW of demand - but we don't need generation that always supply 5GW cheap since wind/solar is much cheaper for base load. What we need is non-base load generation that can jump in at a moment's notice when needed because wind/solar isn't enough. Previously we would use those peak plants from when there was 6GW of demand (or whatever), but now between those peak plants coming down in price and wind/solar being so cheap we don't want that 5GW from plants that cannot adjust to load anymore - we are getting the can't adjust to load from wind/solar.
Baseload is traditionally about generation, not consumption. And baseload generation only makes sense when it is the cheapest option.
When solar and wind produce at near-zero marginal cost, running inflexible baseload beside them just forces cheaper generation to switch off, driving up system costs.
What the grid needs is dispatchable capacity - batteries, hydro, gas peakers (if we must) and demand shifting - that can plug the gaps when cheaper forms of generation cannot.
This is such a tired trope. The differences between the two countries present day energy situation doesn’t tell you anything about how the world should proceed tomorrow.
Unless you have a time machine that you can use to get every country to build state subsided nuclear 50 years ago.
That's the current load when the pricing structure actively encourages people to use power at night, because that was when it was cheapest to produce in the last century.
What does it look like if you actively encourage people to use power when it is cheapest to produce now?
I guess we'll find out when 3 hours of free electricity at noon becomes a standard offer next year.
I've always been curious why a cost-effective widespread implementation of geothermal energy has never been considered a holy grail of energy production, at least not in the public debate. Much of the discussion is so focussed on nuclear fusion, which seems so much harder and less likely to be reliable.
Since you're comparing it to nuclear, I'm assuming you mean electricity production here, not energy production?
It's always worth remembering that electricity only accounts for ~20% of global energy consumption (in the US it's closer to 33%).
I suspect people confuse these two because in a residential context electricity plays a huge part of our energy usage, but as a whole it's a smaller part of total energy usage than most people imagine.
But any serious discussion of renewable energy should be careful not to make this very significant error.
Only about 30% of the energy in gasoline is converted to useful work in a gasoline car (the 'make metal box go forward' part). The remaining 70% is Rejected Energy (the steam you see going out the tail pipe in winter).
Which (not sure if you did this intentionally or accidentally) brings up an interesting point on the parent comment and the LLNL sankey:
> It's always worth remembering that electricity only accounts for ~20% of global energy consumption (in the US it's closer to 33%).
That "global energy consumption" figure includes a lot of Rejected Energy going out tailpipes and smoke stacks turning burnables into electricity. A secret bonus of wind and solar is if you produce electricity without burning things, you actually decrease the energy demand! If you're not losing 70% of your energy consumption to the Rejected category, you suddenly need a lot less total energy.
Rejected energy means energy that is lost as waste heat without performing any work first. For example, a coal fired power plant may generate 3 megajoules of thermal energy from coal combustion but only deliver 1 megajoule of it as electricity. The other 2 megajoules are lost as useless waste heat.
The 1 megajoule of useful electricity is also ultimately dissipated as low grade heat, but it can do work first (like generating light, or pumping water uphill).
I live in a part of the world that is far below freezing for a significant portion of the year. Thus a large portion of my annual energy usage goes into not freezing to death.
When I drive my daughter to school when it’s -40 fucking degrees, a lot of the energy I use goes into heating my vehicle, swearing, moving and swearing. But this energy also leaks through my windshield, through my exhaust system and through my engine. This energy (heat) doesn’t provide any benefit to anyone and just leaks out into the atmosphere (which we’ve already established is trying to kill me).
That’s rejected energy. Or when it’s below -40, rejected motherfucking energy. :)
A IC car’s heating system normally taps into the engine’s cooling system, so that heat is mostly free. In a pinch you can actually turn the heater on full to help cool the radiator.
I had to do that when my radiator sprang a leak on the freeway and the engine heat kept creeping up. Unfortunately it was late summer and not at all pleasant.
I managed to get to a gas station with some stop leak in stock... If they didn't, I was ready to crack an egg in it.
At home I use 15,000kWh of oil for heating each year (about 10kWh per litre, 1500 litres), and 8,000kWh of electricity (we use a lot more than the average household). For driving that's another 5000kWh a year if at 4 miles per kWh.
So even in a residential context, electricity is only about 1/4 of the demand. Across the whole country it's less than 300TWh out of 1500TWh, under 20%.
That excludes "imported energy" though, as in goods which used energy to make but were then imported.
Drilling is one of those things which used to be extremely expensive but has very gradually come down in price. Thanks, ironically, to the oil industry. It's unsexy because there's no "silver bullet" waiting in the wings.
It's also quite hard to find suitably hot rocks suitably close to the surface.
Focusing on fusion .. I think that's a legacy of 60s SF, when the fission revolution was still promising "energy too cheap to meter".
To be fair, that promise of fission made sense from a purely scientific and mathematical perspective, before running into the practical realities of how its externalities interact with real-world politics. Fission is expensive because in practice it turns out we care quite a lot about proper waste management, non-proliferation, and meltdown prevention.
In a world where anyone could just YOLO any reactor into production with minimal red tape, consequences be damned, fission energy would actually be extremely cheap. Hence the optimism around fusion. The promise of fusion is an actualization of last century's idealistic conception of fission. It can be a silver bullet for all intents and purposes, at least once it's established with a mature supply chain.
I fully understand that waste management of fission reactors is a Very Big Deal. But I still stand behind the argument that opposing nuclear power in the 70s and onward is possibly the biggest own goal the environmental movement has ever achieved.
At worst, nuclear waste contaminates a discrete section of the Earth. Climate change affects literally everywhere. The correct answer would have been to aggressively roll out fission power 40-50 years ago and then pursue renewables. You can argue that other solutions would make fission power obsolete, but we would have been in a much better spot if it'd at least been a stepping stone off fossil fuels. Instead, we have 40-50 years of shrieking and FUD from environmentalists over an issue that can be kept under control with proper regulation. The US Navy has operated reactors for over 60 years without incident, proving it can be done with proper oversight.
TL;DR nuclear has issues, but I'd take it over coal every day and twice on Sundays, at least until something better can scale.
People want houses. Planners can either yell and stomp their feet about this or adapt to circumstances. It's like electric cars. People want cars. Better they have the ability to have an electric SUV or pickup, because if you try to force them into little tiny econoboxes or lecture them about how they should really be using mass transit, they're just going to flip you the bird and walk away.
Similarly, better to have people be able to have reasonably energy-efficient houses than demanding they all live in apartments.
People want a place to call home. Those come in many shapes and sizes. Denser living does not mean a smaller living space. By building 'up', you can provide both.
The only ones demanding anything are those who show up to try and stop apartments.
(Source needed. This probably depends on a lot of variables in play.)
Plenty of people in dense urban areas are happy with living in an apartment and, where I live, buying a condo in the city is at least as frequent as buying a house 20 km away from it for the same price.
Living in suburbia has its downsides - long commute, very limited entertainment and cultural possibilities, very limited choice in schools. Not everyone loves cutting the lawn etc. either, I surely don't. If any of your family members has any disease that could flare up, ambulance response time tends to grow worse with the growing distance.
Of course, a lot depends on factors such as "is the transport authority willing to make public transport actually safe and nice". That requires keeping raving drugged lunatics out of it, plus paying enough money for it. AFAIK in the US, Republicans have an ideological problem with the "paying money for it" part and the Democrats have an ideological problem with the "suppressing antisocial behavior in it" part.
Back then, it affected everyone in two ways, which were the things Greenpeace campaigned against: nuclear weapons, especially overland testing, and dumping waste at sea.
Chernobyl took out Welsh farming for years, and in a few places decades, because it spread a thin layer of bioaccumulative poison over the whole of Europe.
Neither of these have anything to do with running a well-regulated nuclear power program. Chernobyl happened because of the apathy and incompetence endemic to any Marxist-Leninist system, not because a modern democratic state is incapable of regulating the nuclear power industry.
Know what else spreads a thin layer of poison over the whole of the world? Coal power.
I agree. I think the correct environmentalist position at that time wouldn't have been to oppose nuclear, but to advocate for improvements, streamlined approvals of improved designs, and public investment or incentives.
I wasn't really commenting on the merits of 20th century environmentalist movements, more raising the general point that fission power has inherent costs which weren't reflected by narrow 1950s analyses of how much energy was extractable from U-235. Operation of a fission plant requires much more capex and opex than it would if we didn't care about cleanliness (waste management), security (fissile material theft prevention), or safety (meltdown prevention).
Fusion power is more complex to invent and practically depends on modern technologies that didn't exist 50 years ago, but once the first demonstration plants are operational, marginal costs to deploy and operate more should be much lower and ultimately become very low at scale.
> Drilling is one of those things which used to be extremely expensive but has very gradually come down in price. Thanks, ironically, to the oil industry. It's unsexy because there's no "silver bullet" waiting in the wings. It's also quite hard to find suitably hot rocks suitably close to the surface.
That's basically it. Most geothermal plants today are in locations where there are hot rocks, maybe geysers, close to the surface. "Deep geothermal" gets talked about,
because temperatures high enough for steam are available almost everywhere if you can drill 3,000 meters down. There are very few wells in the world that deep, not counting horizontal drilling runs.
The economics are iffy. You drill one of the most expensive wells ever drilled, and you get a medium-pressure steam line. Average output is tens of megawatts.[1]
The economics change when you’re in oil country. My beautiful little province has oil wells drilled between 250 and 2900 metres. Due to corporate ‘issues’ many of these wells are orphaned and remediation becomes a provincial problem. With deep holes and provincially owned electricity and gas companies, geothermal makes more economic sense; it’s robbing a benefit from a big cost centre.
I went to high school with two guys who are working on geothermal as a means to remediate orphan wells. I’m biased in their favour, but the numbers make a lot of sense.
Many others here have talked about the difficulties of geothermal, which doesn't really get to the heart of my question: why the lack of hype around breaking down those difficulties? I appreciate that you took the time to comment on why it isn't so sexy, the SF argument probably has a lot to do with it.
The problems are that rock isn't a good conductor of heat, so once you've cooled a bit down, you have to wait for it to warm up. Warming only happens very slowly at the rate of < 50mW / m² which limits the amount of power you can get out.
Until recently, the geographical locations where geothermal is feasible and economic was very limited. Ironically it is tech from fracking/shale gas that is starting to open up a far wider range of possible sites at lower cost.
The worst earthquake that was induced that way was 3.5, but given that one of the quakes happened in an area that had a catastrophic earthquake in the Middle Ages, some caution might be warranted: https://en.wikipedia.org/wiki/1356_Basel_earthquake
all the machinery used to obtain and maintain an economically viable fusion reaction. Having worked with particle accelerators and synchrotron rings, I'll tell you that stuff breaks down all the time.
The reactor breaking and taking a very long time to repair because the repairs would have to be done remotely, with robots. The structure becomes too activated for people to go inside, even after the reactor is shut off.
The reactor breaks because it's a large device operated at high stresses (power/area, neutron loading). There are many components and joints that can fail.
BTW, this means fusion will be expensive, because getting all those components to be reliable right off the bat becomes expensive. No tiny cracks in the welds means expensive quality control.
Because unless you sit on top of a volcano, amount of renewable geothermal energy is minuscule. In most places on Earth it's somewhere around 40 mW/m2 (i.e. accounting for conversion losses you need to capture heat from ~500 m2 to renewably power one LED light bulb!). In other words, in most places geothermal plant acts more like a limited battery powered by hot rock, so unless drilling is extremely cheap, it does not make economic sense compared to other energy sources.
While it's true that a geothermal plant is a limited battery powered by hot rock, that doesn't mean it doesn't make economic sense compared to other energy sources.
> In most places on Earth it's somewhere around 40 mW/m2 (i.e. accounting for conversion losses you need to capture heat from ~500 m2 to renewably power one LED light bulb!)
Ground-source heat pumps extract about 1000 times more power from ground loops, where does the difference come from?
Ground-source heat pumps are irrelevant to geothermal energy sources, and it's unfortunate that the article mentioned them. Ground-source heat pumps are just storing heat from the air during the summer and retrieving it during the winter.
A number of sources. Often the air above - ground source relies on the ground being the average temperature of the year round air once you get deep. They also tend to run in heating mode half the year, and cooling mode the other half.
I think it mainly depends on how easy it is to access that energy. I went to Tuscany last year and to my surprise there were geothermal plants everywhere. I have never heard about these plants beforehand, but here they are in Italy quietly powering the countryside and heating greenhouses to grow basil all year around.
Probably because not everywhere on earth has the same easy access that Iceland has. The article mentions this:
> There aren’t gates of Hell just anywhere. A kilometre below ground in Kamchatka is considerably hotter than a kilometre below ground in Kansas. There is also readily accessible geothermal energy in Kenya (where it provides almost fifty per cent of the country’s energy), New Zealand (about twenty per cent), and the Philippines (about fifteen per cent)—all volcanic areas along tectonic rifts. But in less Hadean landscapes the costs and uncertainties of drilling deep in search of sufficient heat have curtailed development.
There is a crazy amount of energy available everywhere but it is not in the interest of the very powerful very wealthy existing players. This isn't some grand CONSPIRACY. For example oil companies may construct energy investment portfolios that would quite sensibly acquire promising energy related research. They do a simple cost benefit analysis then chose to modestly further research it or shelve it. They turn it into valuable pieces of paper that accumulate value over time. What is there for them not to like about it?
I like how David Hamel put it: We live in this thin sliver on the surface of the planet where it is reasonably peaceful. This is the tranquility! It's a good thing! If you go up or down by a mere few miles there is so much energy it kills you.
Instead of drilling deep, there is also an intersting case for storing cheap solar energy as hat in piles of dirts in the summer to power turbines in the winter: https://austinvernon.site/blog/standardthermal.html
Purely as an aside, I had the pleasure of visiting Iceland in August and it was great. Truly beautiful, rugged land.
Another way they've utilised geothermal energy is with large, sophisticated greenhouses which allow growing of many produce they would otherwise import. I only had the opportunity for a brief visit but a lot of it looked hydroponic with really interesting monitoring and control technology. (Plus the biggest bees this Antipodean has ever seen! These suckers were so big they didn't buzz, they rang the doorbell.)
My favorite memory is following a map to a small isolated hot spring off of some random gravel road in the middle of nowhere. It consisted of a hot-tub-sized pool and a shower.
Whoever was there before had left the shower running. We were the only people there, and hadn't seen anyone pass us on the (dead end) road, so it must have been on for quite a while.
Only when I went to for my pre-soak shower did I realize that it didn't actually have any kind of user-accessible way to turn it off.
Iceland's hot water was a culture shock to me in 2 ways:
1. The host at our apartment encouraged us to leave the windows cracked and the heat on for good air circulation.
2. The hot water (at the taps) has a sulfer smell, because it's (also) piped geothermal water. My host explained they also had a water heater upstairs in their home because they preferred "heated cold water" over "hot water", which is a funny distinction to those of us who do not have the latter.
When heating is dirt (heh) cheap, it doesn't cost much to do things like put big hot tubs and heated pools outdoors, like they do in Reykjaviks swim halls. It's really nice.
I was wondering how feasible it would be to reuse abandoned oil pumps for geothermal energy. A closed loop system [1] would probably be the most appropriate, with energy generation by spinning of a turbine by steam that gets recycled. I don't have the expertise and was wondering if someone can share a bit of knowledge with the rest of us.
I don't have knowledge, but my understanding based on a conversation I had on the topic with a friend of mine is that the "let's use hydraulic fracturing to make geothermal energy feasible in North America" idea involves drilling very far down. Oil is on [average][1] about a mile down, while [one of Fervo's wells][2] is three times deeper.
There are scifi stories that have that kind of premise. Here's one, about electric power: "Damned if you don't" by Randall Garrett (https://www.gutenberg.org/cache/epub/24064/pg24064-images.ht...). I think there was also one about teleportation, although I can't remember where I read it.
People across the road from have geothermal, driven by a 1.5m-deep pond right near their house. Their heat never costs more than $100 a month in the winter.
That's a different "geothermal" - the correct name is "ground source heat pump" or in your neighbor's case, a pond-source heat pump. Those exploit the temperature stability that occurs some small numbers or meters subsurface for heating in the winter and cooling in the summer.
"Geothermal energy" involves drilling down to hot rock to tap intense heat to run a turbine that produces electricity.
Well, heat pumps are awesome, but ground-source is overkill for many places where the air temps don't fall too low (and it's a lot harder to drill holes behind your house).
I hadn't realized that the IDDP had hit magma! That's very exciting! Obviously I'm very out of date, since that was in 02008.
However, I'm skeptical that geothermal energy can be economically competitive with solar without major innovations in heat engines, no matter how abundant the energy is and how easily you can get that energy to the surface.
https://www.eia.gov/analysis/studies/powerplants/capitalcost... outlines the estimated costs (five years ago) of a 650MW peak ultra-supercritical coal power plant without carbon capture; the total capital cost estimate comes out to US$2.4 billion, which is US$3.70 per peak watt. Of that, I think the only line item that wouldn't be the same in a 650MW peak ultra-supercritical geothermal plant is "Mechanical – Boiler Plant", which is US$905 million, leaving US$1.5 billion, US$2.30 per peak watt. (I'm not even sure you could eliminate even all of that US$905 million in a geothermal plant; some of it might be plumbing you'd also need to pass heat from your downhole heat exchange fluid with the ultra-pure deionized water you use to drive the delicate steam turbine. But let's suppose you could.) Of that US$1.5 billion, US$155.2 million is "Mechanical – Turbine Plant", so the turbine alone costs 24¢/Wp.
But SEIA last year published https://www.seia.org/research-resources/solar-market-insight.... They have a set of cost breakdowns for “turnkey installed price” for power plants, coming in at 98¢ per watt for “utility-scale fixed-tilt”, slightly higher than the previous year and almost half due to about 40¢ for the PV module itself. Residential is at 325¢, with about 20¢ for the PV module. That's even in the US, where the EIA report's estimates were sited, despite the US's prohibitive import tariffs on solar panels from China, which makes most of the world's solar panels.
Mainstream PV modules are now 12.3¢ per peak watt https://www.solarserver.de/photovoltaik-preis-pv-modul-preis... (except in the US), which would drop SEIA's cost estimates from 98¢/Wp to 70¢/Wp, even in the absence of any other cost optimizations in solar farm design.
Now, utility-scale fixed-tilt solar farms typically have a capacity factor of around 20%, depending on latitude, because the sun is below the horizon half the time and somewhat slanted and/or clouded most of the rest of the time, so 70¢/Wp is really about US$3.50 per watt, not counting the batteries. But geothermal typically only has a capacity factor of around 74% in the US https://en.wikipedia.org/wiki/Capacity_factor#Capacity_facto... so US$2.30/Wp is really US$3.10 per watt.
That leaves you 30¢/Wp (74% × ($3.50 - $3.10)) for geothermal exploration and drilling. And if you can reduce the 82% of the solar 70¢/Wp represented by the non-PV-module costs by a little bit, or if you're equatorial enough that your PV capacity factor is 23% or above, that's going to zero or negative. I think the average PV capacity factor in California is something like 29%, though that isn't fixed-tilt and therefore has slightly higher costs.
Also note that the PVXchange page I linked above lists "low-cost" solar panels as having fallen to €0.050/Wp this month, a new historic low, which is 5.9¢/Wp. That's a 50% price decline from two years ago.
Fundamentally I think it's just going to be very hard for 24¢/Wp steam engines to compete against 5.9¢/Wp solar panels. The steam engines have the additional disadvantage that, to get the price even that low, you need enormous degrees of centralization—on the order of a few thousand power plants for the whole population of the US. This requires long-distance electrical transmission lines as well as local distribution lines, which are both substantial costs of their own as well as wasting a double-digit percentage of the energy. Local electrical generation eliminates those costs; you can charge your cellphone or your angle-grinder battery directly from a 5.9¢/Wp solar panel with no more electronics than a couple of protection diodes, not requiring the rest of the 70¢/Wp in the utility-scale solar plant.
This cost analysis is completely indifferent to where the heat to boil the water comes from, so it applies equally well to nuclear power, except for Helion.
The exceptions would be in places where geothermal energy is available and solar energy is either unavailable or very marginal: the surface of Venus, the ocean floor, Antarctica, Svalbard, etc.
Does anyone have a trustworthy estimate of the costs of drilling? Even drilling into cold rocks (for oil) would be a good start, even if hot rocks are more expensive to drill into. The article says that Fervo has raised US$800 million in capital and drilled three appraisal and demonstration wells with it so far, which gives us a ballpark of US$200 million per well. This does not offer much hope that drilling costs will be a minor fraction of the costs of a geothermal plant.
The article unfortunately doesn't enter into this analysis at all.
I am somewhat skeptical of this figure:
> Geothermal energy production in the U.S. at that time [i.e., 02005] was around three or four thousand megawatts.
https://en.wikipedia.org/wiki/Electricity_sector_of_the_Unit... says that geothermal energy production in the US in 02022 was 16.09 billion kWh per year, which is 1825 megawatts. Does that mean that geothermal energy production fell by about half between 02005 and 02022? More likely Rivka Galchen got confused.
It's unfortunate that the article also confuses ground-source heat pumps (thermal energy storage) with geothermal energy sources. It's a common confusion, and it makes conversations about geothermal energy unnecessarily difficult.
It's nuclear fission. It's always been nuclear fission (well, at least since the '50s) and it will continue to be until we commercialize fusion reactors. Everything else is nice to have but it's like NIH syndrome.
Geothermal is fission, and wind, solar, and batteries are fusion at a distance. In both cases, the failure scenarios are benign vs traditional fission generation. It's fine to keep striving for fusion humans control, but the problem (global electrification and transition to low carbon generation) is already solved with the tech we have today. It took the world 68 years to achieve the first 1TW of solar PV. The next 1TW took 2 years. Globally, ~760GW of solar PV is deployed per year (as of this comment), and will at some point hit ~1TW/year of deployment between now and 2030.
Geothermal is a great fit for dispatchable power to replace coal and fossil gas today (where able); batteries are almost cheaper than the cost to ship them, but geothermal would also help solve for seasonal deltas in demand vs supply ("diurnal storage").
Failure scenario in modern fission reactors is also benign. Reactors are designed to lock down to prevent any leaks.
We deploy solar PV capacity, this doesn't mean we actually get that much power from the deployments. Nuclear fission provides reliable, baseload power, and doesn't require huge battery arrays to compensate for the sun setting or winds calming.
Enough renewables are deployed annually to replace the global nuclear fission fleet, year after year, even when accounting for capacity factor derating (to make a like for like comparison). The race is over, and renewables (with batteries) won. If you can find someone unsophisticated to invest in a fission reactor that takes billions of dollars and 10-15 years to build, more power to you. There will be no need for it by 2035-2040 when it prepares to send its first kwh to the grid.
(and to stay on topic for this thread, geothermal is a component of this when geothermal potential exists, cost is competitive, and dispatachability is a requirement to push out fossil generation in concert with renewables, hydro, legacy nuclear, battery storage discharge, and demand response)
> If you can find someone unsophisticated to invest in a fission reactor that takes billions of dollars and 10-15 years to build
Unsophisticated investors like the Chinese government? 'Nearly every Chinese nuclear project that has entered service since 2010 has achieved construction in 7 years or less.'
They dabble in nuclear, but it is not their focus. China can do what the developed world cannot because they are a command economy with less expensive labor, which will only last for a bit longer due to their structural demographics. Unless the developed world no longer has labor regulations, developed world wages, and capital based allocation systems, my statement stands with regards to investment. If capital and labor does not matter, certainly, anything is possible (Paraoh demanding pyramids, for example).
Your citation comes from an organization with pro nuclear bias.
China built more solar power in the last 8 months than all the nuclear power built in the entire world in the entire history of human civilisation. And even if you adjust for utilisation rate to compare against nuclear utilisation China built more solar power generated per hour than all the nuclear power currently in operation generate in an hour - and did so in 12-18 months - https://bsky.app/profile/climatenews.bsky.social/post/3lggqu... - January 23, 2025
If France–a country known for its strong labour laws and unions–could transition to nuclear in the '70s, any Western country can do it.
Even if the Western world lags behind due to labour regulations, the cost still pays off in the long run due to overall less complex infrastructure and stable, AC baseload power. You are thinking only about the cost of building. What about the cost of maintaining all that infrastructure? Huge solar and wind farms spread out over vast areas, essentially destroying the local ecology? NPPs have a relatively tiny footprint.
Every cited source has a bias. You think 'Clean Technica' is unbiased? Come on.
The options in the '70s were much different from those of today. And for France specifically what they have underground (lots of uranium, no oil, no gas & no coal) strongly suggested exactly one way forward.
They’re at ~60% total power from renewables in 2025, and increasing every quarter. I’d say they’re doing pretty well! The coal is unfortunate, but was due to the Ukraine war and gas situation.
This is basically nonsense to the extent that it is becoming difficult to extend the presumption of good faith to you. In the 70s solar panels cost US$25+ per peak watt, in 02021-adjusted dollars: https://en.wikipedia.org/wiki/Solar_energy#/media/File:Solar...
Installing a gigawatt of solar power generation capacity for US$25 billion is in no way comparable to installing a gigawatt of solar power generation capacity for US$59 million.
Wind power has experienced a similar but less extreme cost decline.
> If France–a country known for its strong labour laws and unions–could transition to nuclear in the '70s, any Western country can do it.
France had to nationalize EDF because they could not afford the costs associated with their nuclear fleet. The 70s are 50 years in the past, and are not what the future will look like.
This is also why Spain plans to retire its remaining nuclear generators, and go all in on renewables.
Spain’s Nuclear Shutdown Set to Test Renewables Success Story - https://www.bloomberg.com/news/articles/2025-04-11/spain-s-n... | https://archive.today/4fB7K - April 11th, 2025 (“Spain is a postcard, a glimpse into the future where you’re not going to need baseload generators from 8am to 5pm” with solar and wind providing all of the grid’s needs during that time, said Kesavarthiniy Savarimuthu, a European power markets analyst with BloombergNEF. Still, she said, there is a reasonable chance this goal may take longer than expected and “extending the life of the nuclear fleet can prove as an insurance for these delays.”) (My note: As of this comment, Spain has 7.12GW of nuclear generation capacity per ree.es, and assuming ~1GW/month deployment rate seen in Germany, could replace this capacity with solar and batteries in ~28-36 months; per Electricity Maps, only 17.25% of Spain's electrical generation over the last twelve months has been sourced from this nuclear)
Tangentially, Europe has enough wind potential to power the world, for scale.
Personally, I've invested ~500k EUR in a Portuguese Golden Visa fund invested in renewables (IRR is ~7-13%). Macro speaking, renewables investments keep hitting new records. I am convinced, and if you are not, I would strongly suggest consuming more data, because you appear to have a potential blind spot in your mental model on this topic.
»Enough renewables are deployed annually to replace the global nuclear fission fleet, year after year, even when accounting for capacity factor derating (to make a like for like comparison).«
Wind and solar do not replace conventional power plants and never will.
Heck, Germany tried that on the small island of Pellworm and failed and yet some people think this will work out for the whole country.
Things are more expensive when we keep reinventing the wheel and trying to do new things instead of just reusing proven designs. Remember that solar power also used to cost wheelbarrows of cash back in the day. When you do something repeatedly, it becomes less expensive over time.
Nuclear is actually the leader in waste management. No other energy source has as complete a story. Eg what happens to solar panels when they EOL in 25 years? They go into landfills and leach toxic chemicals into the ground. These chemicals, like lead and cadmium are toxic forever. They have no 'half-life' in which their toxicity reduces.
Solar panels do not become useless in 25 years and need to be discarded, do not leach toxic chemicals, and do not contain cadmium. They do contain small amounts of lead, but leaching metallic lead out of landfills is very difficult and probably does not ever happen unintentionally.
A nuclear plant about 50 miles from my house was closed 15 years ago. The spent fuel rods will be stored there indefinitely until a federal facility is built.
Solar panels are recycled at almost 100% of total materials. Redwood Materials (founded by Tesla's former CTO) has already established a supply chain to ingest and recycle EV and stationary storage batteries at scale. The problem is that the hardware is lasting longer than expected, and meaningful recycling volume does not yet exist.
Conversely, ~95,000 metric tons of nuclear waste in the US does not have permanent storage or recycling solutions, as of this comment, and there is no plan for long term storage or recycling. Nuclear generation is experiencing a negative learning curve; we keep spending more the more we attempt to build it.
(solar PV panels have a 25-30 year service life, at which point they will still produce power at ~80-85% initial rating, batteries have a 15-20 year service life, with sodium ion chemistries estimated to have up to 50 year service life assuming once daily cycling)
> Solar panels are recycled at almost 100% of total materials.
That's very clever wording. If someone glances at this sentence they might interpret it to mean that almost all solar panels are recycled. But your own citation tells a different story: https://e360.yale.edu/features/solar-energy-panels-recycling
> Today, roughly 90 percent of panels in the U.S. that have lost their efficiency due to age, or that are defective, end up in landfills because that option costs a fraction of recycling them.
Let's compare to spent nuclear fuel, which we know for sure does not end up in landfills. I am talking about today, not some hypothetical utopian future. Today, NPP spent fuel is safely sequestered while solar panels are dumped into landfills.
> nuclear waste in the US does not have permanent storage or recycling solutions
It does, it's just not built yet because it doesn't make sense to do it now. In a few decades, maybe a century we will have commercialized fusion reactors. Once we do, we switch to fusion completely and build the deep geological repositories or whatever other solution makes sense then. Or we can even recycle the spent fuel–the only thing stopping us from doing that now is misguided US politics (as usual).
> we keep spending more the more we attempt to build it.
It's capex. We are investing in nuclear technology. If you have a proven design and build the reactors at scale, the costs will flatten or decline, which is obvious to anyone who knows about economies of scale.
Look at Electricity Maps and realize that France is the only large industrial country where electricity generation is permanently carbon-free and cheap.
Yes, but unfortunately that is because it is coasting on decades old labor and capital investment that will not be made again. It is not permanent, as it will cost tens of billions of euros to continue to operate those generators reaching the end of their service life.
Norway, Iceland and British Columbia are other examples and are more carbon-free than France is. The latter isn't a country and the former don't count as "large industrial"?
It could be but the US and EU have so far been unable to build commercial fission reactors without going 2x+ over budget in time and money. China is having success but even they are not projected to have nuclear account for more than single digit percentages of their generation.
Maybe SMR's, thorium, 4th gen, etc will work out, but maybe not.
The US and Russian Navies deciding to remain mostly petroleum-fueled is one of the strongest arguments against nuclear becoming very cheap: surely they would do it if it wasn't ruinously expensive, because it eliminates the national security risk of a petroleum blockade and simplifies at-sea logistics immediately.
Ive been very pro nuclear my whole life, but a part of me is disheartened by the mega projects that commercial fission deployments have become (even if the reasons are bad) that’s a problem that nerfs traditional fission. If nuclear remains both political, extremely bureaucratic and requires public investment, it just won’t be the solution, and not because the tech or physics is bad, but the decision makers & investors can no longer organize large infrastructure projects effectively (except maybe China). This is not unique to nuclear.
Having smaller scale local power generation, whether it’s SMRs, solar, wind or geothermal, there’s a huge advantage in terms of economy, investment, and politics.
Nuclear has broad bipartisan support, and the Trump administration is heavily into it, so I wouldn't count it out just yet. If the various Green parties of the Western world ever come into power though, we are cooked.
But that illustrates the point. Most investors don’t want to put money towards something that may be put on indefinite hold depending on political winds. These projects are often much longer than presidential terms.
It always has been. Our problem is switching over existing infrastructure without asinine complainers ruining the revolution. We can't even declare total victory with LED bulbs over incandescent. The war to have solar plants over more coal is falling back to coal thanks mostly to AI. Pushback on geothermal will arrive, I guarantee it.
> We can't even declare total victory with LED bulbs over incandescent.
The LED bulbs I have access to (whatever's in the aisles at Home Depot, Costco, etc.) fail much more frequently than the incandescent bulbs I used to buy, and produce an uglier light that is less warm even on the softest/warmest color settings.
My suspicion is that incandescents were at the "end" of their product lifecycle (high quality available for cheap) and LEDs are nearing the middle (medium quality available for cheap), and that I should buy more expensive LED bulbs, but I still think that there are valid "complaints" against the state of widespread LED lighting. I hope these complaints become invalid within a decade, but for now I still miss the experience of buildings lit by incandescent light.
The other thing with AI--the LED revolution was led on this idea that we all need to work as hard as we can to save energy, but now apparently with AI that's no longer the case, and while I understand that this is just due to which political cabals have control of the regulatory machinery at any given time, it's still frustrating.
In many cases you can break one of the resistors off the LED bulb's printed-circuit board and run them at two-thirds of the power so they last forever. In other cases the surgery required is a little more involved than just snapping a surface-mount resistor off with pliers.
The light color they call "daytime" is around 5000K, so I expected it to look like being outside in the sun; but instead I got a cold blueish vibe. The problem? Not enough power! I got the equivalent of a moonlit room.
So I got this 180W LED lamp (that's actual 180W, not 180W equivalent) [1]. It's so bright I couldn't see for 5 minutes. I put two in my office on desk lamps. The room now looks like being outside, without the "ugly blue" tint, even though the product says it's 6000K. The days of my SAD suffering are over!
> The LED bulbs I have access to (whatever's in the aisles at Home Depot, Costco, etc.) fail much more frequently than the incandescent bulbs I used to buy, and produce an uglier light that is less warm even on the softest/warmest color settings.
LED lamps work just fine, you just need to pay more attention when you’re buying them. Philips makes decent LED lamps.
Make sure you’re buying lamps with 90+ CRI, that will help with the quality of light. 2700K is a good color temp for indoor living room/dining room/bedroom lighting, 3500-4000K for kitchen/garage/task lighting.
You also need to buy special lamps if you put them in an enclosed fixture, look for ‘enclosed fixture’ rated lamps. Regular LED lamps will overheat in an enclosed fixture.
Maybe buy your bulbs somewhere else? I'm yet to replace any of the LED bulbs I've bought over the past 15 years and honestly can't even remember the last time a bulb failed.
Actually, since posting this I've vaguely remembered a previous discussion on here about differences between LED bulbs sold in the US and those sold in UK/EU so maybe that explains it.
[CITATION NEEDED] They do not. If you take the mean, median, and mode of the failure lifetime for LED bulbs sold at these stores and compare them to the failure times of incandescent bulbs, I also guarantee you are empirically wrong here.
I believe this is true for the LED technology compared to the incandescent technology as a whole, but I'm simply turning over bulbs at a far higher rate than I did in the incandescent days. Often the LED bulbs are failing within a year under normal usage patterns. It's possible that using modern LEDs in old fixtures is causing some kind of issue.
Are your LED lamps failing in enclosed fixtures? You need to buy special lamps for enclosed fixtures, regular LED lamps will heat up too much for enclosed fixtures.
Look for ‘enclosed fixture rated’ LED lamps for enclosed fixtures.
There is an enormous push to build and power data centers in the DC / Northern Virginia region, and there's legislation in West Virginia right now requiring all coal-fired power plants to operate at at least 69% capacity at all times to support it.
> “West Virginia has numerous coal plants that have powered this country for decades. We need these plants to remain operational,” [WV Governor] Morrisey said. “… We will never turn our backs on our existing coal plants and we will work with the federal government to pursue new coal-fired generation.”
The only way new coal plants get built from today on is with massive lifetime subsidies, because they are uncompetitive. Ie, if they get built it’s for dumb politics not economics
> The war to have solar plants over more coal is falling back to coal thanks mostly to AI.
Also, due to solar not panning out at scale.[1]
More seriously, coal is just cheaper and, with incentives being removed for green energy, it's the cheapest and fastest option to deploy. It's dead simple and well understood reliable power.
I see yow it can read that way but it isn't what I said. Coal plants exist, either shuttered or running low loads due to financial incentives (not favoring them).
Studies show solar is cheaper but businesses continue to choose coal. I think the entity who's entire existence depends on them making the correct financial choice is a much better indicator of economic reality than a study made by people who have zero stake (at best) in the game.
I'm all for green energy but I also don't think people are stupid.
The example you chose is of a mirror based Solar system, which yes, is an obsolete technology.
Direct solar continues to be installed at greater amounts every year and coal is economically uncompetitive with basic anything (which is why it is collapsing), and especially against natural gas.
You're exactly right and it raises a question for me. Why do energy generation topics bring people out of the woodworks who cite some very idiosycratic one-off and use it to make out-of-proportion declarations about the utility of a given technology? This is the second one I've seen suggesting solar is doomed when they mean mirrors.
On twitter I saw someone claim PV is useless for heat because non-PV solar water heating is just so much more efficient. Not even true (I think it's a approximately a wash, different advantages in different applications), but very strangely in the weeds on a specific topic. Much too narrow a factual context to substantiate general level claims about solar as an energy writ large.
I think for whatever reason the missing the forest for the trees trap is really potent in energy discussions.
> Why do energy generation topics bring people out of the woodworks who cite some very idiosycratic one-off and use it to make out-of-proportion declarations about the utility of a given technology?
They either have only read propaganda pieces from fossil fuel producers or are trying to create some of those.
I would expect the number of people that honestly don't know anything but propaganda to be way higher than the number of people creating propaganda. But there's probably a selection bias due to HN being a somewhat large site with some influence on SEO and AI training.
I brought up the mirror plant because the molten salt crucible is an example of an attempt to make solar work after hours. It wasn't viable.
Solar+storage is not a solved problem. The storage problem gets continually hand waived away in the conversations about how cheap solar is.
As I said in a sibling comment, I don't think the people running energy companies are stupid. If solar really was cheaper as a baseline power supply, what it needs to be to replace fossil fuels, they'd be doing it.
at some point we will figure out that because we took some much energy out of earths core that it stops spinning and causes the magnetic field to collapse ;-)
Not really how that works. Also earths core is being heated from nuclear decay and tidal effects. It’s getting 10’s or TW worth of heat until the sun expands and eats the earth. https://en.wikipedia.org/wiki/Earth's_internal_heat_budget
10 TW * 1 year = 8,760 TWh / year. The current rate of energy production is ~42TW and slowly dropping over billions of years, so even after efficiency losses gathering 1% of what’s produced is several times current energy consumption.
Baseload generation is useless in 2025. It's in the name; it's called "base load", not "base generation".
Base generation was a cost optimization. Planners noticed that load never dropped below a specific level, and that cheapest power was from a plant designed to run 100% of the time rather than one designed to turn on and off frequently. So they could reduce cost by building a mix of base and peaker generation plants.
In 2025, that's no longer the case. The cheapest power is solar & wind, which produces power intermittently. And the next cheapest power is dispatchable.
To take advantage of this cheap intermittent power, we need a way to provide power when the sun isn't shining and the wind isn't blowing. Which is provided by storage and/or peaker plants.
That's what we need. If added non-dispatchable power to that mix than we're displacing cheap solar/wind with more expensive mix, and still not eliminating the need for further storage/peaker plants.
If non-dispatchable power is significantly cheaper than storage and/or peaker power than it's useful in a modern grid. That's not the case in 2025. The next cheapest power is natural gas, and it's dispatchable. If you restrict to clean options, storage & geographical diversity is cheaper than other options. Batteries for short term storage and pumped hydro for long term storage.
The right answer is 'yes to all the above'. Yes, we need solar. Yes, we need wind. Yes, we need batteries and, yes, we should be looking at geothermal. Solar has shown us, again, how artificially holding back a technology for decades has massive costs. Investing a few billion into geothermal right now is cheap and can only lead to a more durable energy infrastructure in the future. There are all sorts of benefits to a rich ecosystem of power generation. Solar and batteries may be amazing but global supply chains can be disrupted. Similarly, having multiple solutions means that niche use cases have more options and a larger likelihood of finding an acceptable solution. So, yes to all of the above. We are big enough to try them all.
> Solar and batteries may be amazing but global supply chains can be disrupted.
Solar and batteries aren't consumables, so they're not particularly vulnerable to supply chain disruption. If we lose our supply of batteries, we'll have ~10 years or so to find an alternate supply. We won't be able to do new installations during the disruption, but existing installations don't stop working.
Unlike a fossil plant when the supply of fuel is disrupted.
> but existing installations don't stop working.
They will, albeit slowly.
You may need small amounts of rare earth elements. Those are definitely a supply chain nightmare.
nobody ever seems to recognize the benefits of Modularising your grid as well.
Ukraine is an excellent example of why centralizing your grid energy source is a bad plan... but not just for war situations. If you have an agile, adaptable modular grid you can recover for any form of disaster (natural or man made) very quickly and cheaply.
I really feel this is an under valued aspect of electrification and greening of the power sources we use.
This feels a bit like talking in hindsight.
With fossil power plants, the bigger plants were more efficient. This lead to centralization. We now find ourselves in a situation where you can end up with a lot of small/local generation.
What happened in Ukraine can probably happen in almost every developed country today as this was all built/planned in a different time.
yeah I'm not saying that they messed up, I'm saying that we dont appear to be taking note from the situation. Doing better based one the world as it is now and how history has played out.
One thing which is needed too is spinning load, the grid depends on having enough inertia to maintain the frequency. Flywheels I assume would do that.
This is being done and it's called synthetic inertia. Just with capacitors and batteries instead of spinning motors.
Caterpillar provides some really neat small scale flywheel UPS - used in places like hospitals where it would be very bad to lose power. They last long enough for the diesel gennies to start up.
I've worked on mine sites that use this as well.
Inverters and batteries (or any other DC source) are also very good at doing this.
Not grid following inverters, or "any DC source", as we saw in Spain in Summer
From what I saw: In Spain, inverters are not allowed to provide voltage control, and what we saw in Spain, was a voltage spike that caused generators to drop offline, which then caused frequency issues.
Nothing to do with the blackout in Spain - https://www.reuters.com/business/energy/what-caused-iberian-... - voltage surge and various thermal power generators failing to provide the voltage correction services they were being paid for
But yes, grid following alone does not provided the required stability - synthetic inertia etc needed
Yes, if you don't install grid stabilization inverters, they don't supply grid stabilization.
Ignore the clickbait headline here: Australia’s Solar Boom Is Breaking the Grid - Or Is It?
It's a sub 15 minute actual grid engineering for lay public explainer video (I know, I'm not a video fan either)
A better duller title might be: How Australia's Grid is being adapted to Solar Boom
https://www.youtube.com/watch?v=qavFbOpt4jAModern geothermal is dispatchable. It's a really good compliment to wind and solar https://climateinstitute.ca/safe-bets-wild-cards/advanced-ge...
But is it usefully dispatchable? Nuclear can be made dispatchable but it's not usefully dispatchable because the costs are fairly similar whether the plant is on or off.
Like nuclear, I believe geothermal has high capital cost and low running costs, suggesting that it isn't usefully dispatchable.
But that's too simplistic. A big limitation of geothermal is that rock has poor thermal conductivity. So once you remove heat it takes a while for it to warm up again. If you're running it 100% then you need a large area to compensate. OTOH, if you're running it at a lower duty cycle you likely need less area.
So if you know the duty cycle in advance, then you can likely significantly reduce costs. Yay!
But that also means that you likely can't run a plant built for low duty cycles continuously for 2 weeks during a dankelflaute. It's likely great for smoothing out daily cycles, but not as good for smoothing out annual cycles. That means it's competing against batteries, which are also great for smoothing out daily cycles, and are very inexpensive.
> I believe geothermal has high capital cost and low running costs
Higher capital costs, but not nuclear high capital costs.
> That means it's competing against batteries, which are also great for smoothing out daily cycles, and are very inexpensive.
It likely would supplement batteries rather than compete against them. A battery buffer would allow a geothermal plant to slowly rise to load and fall as that load goes away.
A very large battery can store 200MWh worth of energy. The largest geothermal plant produces 1.5GW. (A lot of the large plants look like they are in the range of 100->200MW). Presumably those plants can run for more than a few hours which ultimately decreases the amount of batteries needed to smooth out the demand curve.
Nuclear produces very dangerous substances. The long term cost to guard us from them for a million years and the risk that something gets out of control are extemly high.
That’s a lot of words to admit that geothermal has its place.
That wasn't the conclusion, though. The conclusion was that dispatchable geothermal is competing against daily cycling batteries, a competition it's likely to lose on cost.
> pumped hydro for long term storage.
You are using long-term in an extremely vague way.
Pumped hydro is not a solution for seasonal storage or yearly storage. Seasonal variation can be a problem in higher latitudes.
For example we have a serious problem in New Zealand where our existing "green" hydro lakes are sometimes low and our economy is affected: creating national power crises during dry years. We use coal-burning Huntley and peakers to somewhat cover occasional low hydro generation.
Unfortunately our existing generators also have regulatory capture, and they prevent generating competition (e.g. new solar farms) through rather dirty tactics (according to the insider I spoke with).
Apparently much of our hydro generation is equivalent to “run-of-river” which requires the river to flow. Although the lakes themselves are large, they don't have enough capacity to cover a dry year.
NZ had planned a pumped hydro, but it was expensive: planned cost of 16 billion compared against total NZ export income of ~100 billion. https://www.rnz.co.nz/news/national/503816/govt-confirms-it-... So completely uneconomic risk (plus other problems like NIMBY).
> Although the lakes themselves are large, they don't have enough capacity to cover a dry year.
It was shocking to me to drive by many of the California lakes/reservoirs that were overfull in the spring of 2019 only to hear that they were basically running dry two years later, and realize that as substantial a water storage system as they are, they're not multi-year scale against the required water supply.
Long term storage is definitely the weak point of moving to 100% carbon free electricity. Unfortunately geothermal does not cover this need. If we want to cover a dankelflaute with geothermal, we basically need enough geothermal to cover ~100% of our power needs. Pumped hydro is the best answer we have at the moment, even if it isn't a great answer.
What will likely happen is that people will decide that "99% is good enough", and use fossil generators to cover dankelflautes,
Which is honestly fine, we would be in such an amazing place if we got to 99%
Or just build out nuclear like France and pay just 20 Cents per kWh.
https://particulier.edf.fr/content/dam/2-Actifs/Documents/Of...
State subsided construction and maintenance doesn’t pass straight through to consumer prices.
Also, France can’t build new nuclear for cheap/fast anymore either. They have a program for new reactors, even if they go ahead the first one won’t come online till 2038 by the earliest. We can’t wait that long.
The two nukes that recently came on line in the US were so over budget and timeline that all customers now pay a “surcharge” on their bill to pay for it.
Western counties building nukes is so expensive it makes the cost of electricity go up.
France is a western country with its own economic and labour troubles. The enormous expense of building nukes in the US is entirely its own making and much more complicated than just "western" inefficiency.
You might want to look up flammanville. They built a new reactor there and that also took 20 years or so and was way over budget.
We've built a lot of nuclear in the last century and then largely stopped. A lot of the know how is gone which is what we're paying for now.
Also, in France, all those reactors were largely the same leading to economies of scale when building them. Everything we build today is essentially a one of so you don't get to spread that cost over multiple.
Hyper administrative state-capitalist economies all have the same problem with infrastructure. The US has an image of being more capitalist and efficient, which is true to a degree, but once you get a large-scale project that hits all fed->state->municipal politics it's not much different than France. It's just minor variations of who the mandatory 'stakeholders' are ...who demands a cut and who delays/blocks progress.
As soon as some project is being pitched by politicians as "creating thousands of local jobs" it's either DOA or will be many years late and over budget.
Yes please from the UK, where it’s 27 euro cents per kWh currently.
Its so easy that you can’t name me a single city of more than 10000 people that runs entirely off renewables.
Weakly defined. What does "run entirely off renewables" mean?
We know that in North America, for example, significant energy use comes from transportation and heating requirements, and that at this time, very little transportation is powered by renewables, and not a whole lot of heat either (though both are growing).
On the other hand, the entire current residential electrical demand of the city of Santa Fe (about 82k people) can be met with a single relatively small PV+BESS plant (and might just be if it manages to get built).
Norway and British Columbia are 99% renewable energy and they have many cities larger than that.
P.S. this is a response to the original title, which has since changed making my comment look off-topic.
Suitable locations for pumped hydro are very limited, it is a comparably rare resource.
A lot of mountainous places are dry, and a lot of wet places are flat.
Of the remaining places, some are so unique that they cannot be destroyed by industrial construction (National Parks etc.)
For example, the main ridge of Krkonoše (Riesengebirge) on the Polish-Czech border has a lot of wind and rain and deep valleys, but it is the only place south of Scandinavia with a Scandinavia-like tundra and many endemites surviving from the last Ice Age. Any attempt to construct pumped hydro there would result in a national uproar on both sides of the border.
Pumped hydro just requires a lake at the bottom of a slope. Unlike hydro generation, it doesn't require flow. Here's almost a million locations suitable for pumped hydro: https://re100.eng.anu.edu.au/global/
Two farm dams at a minimum, one at either end of a slope.
You can serve a small town of 500 or so people (plus tourists) with a mini systems for ~ $8 million (AU)
https://news.ycombinator.com/item?id=45332157
Suitable locations for on river pumped hydro are limited.
But off river? The possibilities are vast.
In 2025 the power consumption of my state (NSW, Australia) on any given day will be greater then 5 GW. https://www.aemo.com.au/energy-systems/electricity/national-...
This "there is no base load" idea is a ridiculous myth trivially disproven: every grid on the planet has continuous demands on it and they're quite significant (5 GW is about 50% the day time peaks).
It doesn't matter what the cost is, because later this evening or tomorrow morning I can guarantee you the same thing: my state will need at least 5GW of power to literally keep the lights on.
> my state will need at least 5GW of power to literally keep the lights on.
I think this abstraction is missing the elasticity of demand that can by unlocked by end-to-end dynamic pricing. Probably if the production was cut in half for some day, and hourly price hiked up until demand matches production, customers would still choose to keep most of the lighting while postponing some more energy intensive loads.
You misunderstand the point though. Sure there is always 5GW of demand - but we don't need generation that always supply 5GW cheap since wind/solar is much cheaper for base load. What we need is non-base load generation that can jump in at a moment's notice when needed because wind/solar isn't enough. Previously we would use those peak plants from when there was 6GW of demand (or whatever), but now between those peak plants coming down in price and wind/solar being so cheap we don't want that 5GW from plants that cannot adjust to load anymore - we are getting the can't adjust to load from wind/solar.
We’re trying that in Germany while we’re still heavily dependent on coal while our electricity prices are twice as much compared to France.
I’m sorry, but wind and solar may be cheap, but they don’t provide cheap electricity 24/7.
which is why dispatchable power is required - not coal?
Baseload is traditionally about generation, not consumption. And baseload generation only makes sense when it is the cheapest option.
When solar and wind produce at near-zero marginal cost, running inflexible baseload beside them just forces cheaper generation to switch off, driving up system costs.
What the grid needs is dispatchable capacity - batteries, hydro, gas peakers (if we must) and demand shifting - that can plug the gaps when cheaper forms of generation cannot.
It sounds great in theory but doesn’t work in practice.
Just compare Germany to France.
This is such a tired trope. The differences between the two countries present day energy situation doesn’t tell you anything about how the world should proceed tomorrow.
Unless you have a time machine that you can use to get every country to build state subsided nuclear 50 years ago.
Not even France can replicate their nuclear construction of decades ago.
That's the current load when the pricing structure actively encourages people to use power at night, because that was when it was cheapest to produce in the last century.
What does it look like if you actively encourage people to use power when it is cheapest to produce now?
I guess we'll find out when 3 hours of free electricity at noon becomes a standard offer next year.
I've always been curious why a cost-effective widespread implementation of geothermal energy has never been considered a holy grail of energy production, at least not in the public debate. Much of the discussion is so focussed on nuclear fusion, which seems so much harder and less likely to be reliable.
> a holy grail of energy production
Since you're comparing it to nuclear, I'm assuming you mean electricity production here, not energy production?
It's always worth remembering that electricity only accounts for ~20% of global energy consumption (in the US it's closer to 33%).
I suspect people confuse these two because in a residential context electricity plays a huge part of our energy usage, but as a whole it's a smaller part of total energy usage than most people imagine.
But any serious discussion of renewable energy should be careful not to make this very significant error.
The Lawrence Livermore National Laboratory publishes a great diagram of US energy use: https://flowcharts.llnl.gov/sites/flowcharts/files/2024-12/e...
What does "Rejected Energy" mean in that graph?
Great chart, by the way.
Only about 30% of the energy in gasoline is converted to useful work in a gasoline car (the 'make metal box go forward' part). The remaining 70% is Rejected Energy (the steam you see going out the tail pipe in winter).
Which (not sure if you did this intentionally or accidentally) brings up an interesting point on the parent comment and the LLNL sankey:
> It's always worth remembering that electricity only accounts for ~20% of global energy consumption (in the US it's closer to 33%).
That "global energy consumption" figure includes a lot of Rejected Energy going out tailpipes and smoke stacks turning burnables into electricity. A secret bonus of wind and solar is if you produce electricity without burning things, you actually decrease the energy demand! If you're not losing 70% of your energy consumption to the Rejected category, you suddenly need a lot less total energy.
Rejected energy means energy that is lost as waste heat without performing any work first. For example, a coal fired power plant may generate 3 megajoules of thermal energy from coal combustion but only deliver 1 megajoule of it as electricity. The other 2 megajoules are lost as useless waste heat.
The 1 megajoule of useful electricity is also ultimately dissipated as low grade heat, but it can do work first (like generating light, or pumping water uphill).
It would be nice if before each box where rejected energy is an output, the inputs were split by rejected and non-rejected inputs.
I live in a part of the world that is far below freezing for a significant portion of the year. Thus a large portion of my annual energy usage goes into not freezing to death.
When I drive my daughter to school when it’s -40 fucking degrees, a lot of the energy I use goes into heating my vehicle, swearing, moving and swearing. But this energy also leaks through my windshield, through my exhaust system and through my engine. This energy (heat) doesn’t provide any benefit to anyone and just leaks out into the atmosphere (which we’ve already established is trying to kill me).
That’s rejected energy. Or when it’s below -40, rejected motherfucking energy. :)
"when it’s -40 fucking degrees" Celsius, or Fahrenheit? Oh yeah, it's the same either way :).
A IC car’s heating system normally taps into the engine’s cooling system, so that heat is mostly free. In a pinch you can actually turn the heater on full to help cool the radiator.
I had to do that when my radiator sprang a leak on the freeway and the engine heat kept creeping up. Unfortunately it was late summer and not at all pleasant.
I managed to get to a gas station with some stop leak in stock... If they didn't, I was ready to crack an egg in it.
Do you live out in Siberia or something? Seems like a rough environment for most tech.
Sounds like a very unique experience :)
Not OP, but upper Midwest US and Canada experience this every year, though where I'm at usually only hits -40 if you include the wind chill.
At home I use 15,000kWh of oil for heating each year (about 10kWh per litre, 1500 litres), and 8,000kWh of electricity (we use a lot more than the average household). For driving that's another 5000kWh a year if at 4 miles per kWh.
So even in a residential context, electricity is only about 1/4 of the demand. Across the whole country it's less than 300TWh out of 1500TWh, under 20%.
That excludes "imported energy" though, as in goods which used energy to make but were then imported.
Drilling is one of those things which used to be extremely expensive but has very gradually come down in price. Thanks, ironically, to the oil industry. It's unsexy because there's no "silver bullet" waiting in the wings.
It's also quite hard to find suitably hot rocks suitably close to the surface.
Focusing on fusion .. I think that's a legacy of 60s SF, when the fission revolution was still promising "energy too cheap to meter".
To be fair, that promise of fission made sense from a purely scientific and mathematical perspective, before running into the practical realities of how its externalities interact with real-world politics. Fission is expensive because in practice it turns out we care quite a lot about proper waste management, non-proliferation, and meltdown prevention.
In a world where anyone could just YOLO any reactor into production with minimal red tape, consequences be damned, fission energy would actually be extremely cheap. Hence the optimism around fusion. The promise of fusion is an actualization of last century's idealistic conception of fission. It can be a silver bullet for all intents and purposes, at least once it's established with a mature supply chain.
I fully understand that waste management of fission reactors is a Very Big Deal. But I still stand behind the argument that opposing nuclear power in the 70s and onward is possibly the biggest own goal the environmental movement has ever achieved.
At worst, nuclear waste contaminates a discrete section of the Earth. Climate change affects literally everywhere. The correct answer would have been to aggressively roll out fission power 40-50 years ago and then pursue renewables. You can argue that other solutions would make fission power obsolete, but we would have been in a much better spot if it'd at least been a stepping stone off fossil fuels. Instead, we have 40-50 years of shrieking and FUD from environmentalists over an issue that can be kept under control with proper regulation. The US Navy has operated reactors for over 60 years without incident, proving it can be done with proper oversight.
TL;DR nuclear has issues, but I'd take it over coal every day and twice on Sundays, at least until something better can scale.
A lot of housing politics from 'old school' environmentalist groups are a pretty big own goal as well.
Denser urban living is pretty energy efficient, and forcing lengthy commutes on people because of NIMBYism is a huge waste.
People want houses. Planners can either yell and stomp their feet about this or adapt to circumstances. It's like electric cars. People want cars. Better they have the ability to have an electric SUV or pickup, because if you try to force them into little tiny econoboxes or lecture them about how they should really be using mass transit, they're just going to flip you the bird and walk away.
Similarly, better to have people be able to have reasonably energy-efficient houses than demanding they all live in apartments.
Allowing people to live in apartments is not demanding that they do.
Reversing the downzoning of the 70s - 00s is about allowing construction in cities again.
People want a place to call home. Those come in many shapes and sizes. Denser living does not mean a smaller living space. By building 'up', you can provide both.
The only ones demanding anything are those who show up to try and stop apartments.
People want houses, but absolutely hate other people having houses.
"People want houses."
(Source needed. This probably depends on a lot of variables in play.)
Plenty of people in dense urban areas are happy with living in an apartment and, where I live, buying a condo in the city is at least as frequent as buying a house 20 km away from it for the same price.
Living in suburbia has its downsides - long commute, very limited entertainment and cultural possibilities, very limited choice in schools. Not everyone loves cutting the lawn etc. either, I surely don't. If any of your family members has any disease that could flare up, ambulance response time tends to grow worse with the growing distance.
Of course, a lot depends on factors such as "is the transport authority willing to make public transport actually safe and nice". That requires keeping raving drugged lunatics out of it, plus paying enough money for it. AFAIK in the US, Republicans have an ideological problem with the "paying money for it" part and the Democrats have an ideological problem with the "suppressing antisocial behavior in it" part.
Back then, it affected everyone in two ways, which were the things Greenpeace campaigned against: nuclear weapons, especially overland testing, and dumping waste at sea.
Chernobyl took out Welsh farming for years, and in a few places decades, because it spread a thin layer of bioaccumulative poison over the whole of Europe.
Neither of these have anything to do with running a well-regulated nuclear power program. Chernobyl happened because of the apathy and incompetence endemic to any Marxist-Leninist system, not because a modern democratic state is incapable of regulating the nuclear power industry.
Know what else spreads a thin layer of poison over the whole of the world? Coal power.
I agree. I think the correct environmentalist position at that time wouldn't have been to oppose nuclear, but to advocate for improvements, streamlined approvals of improved designs, and public investment or incentives.
I wasn't really commenting on the merits of 20th century environmentalist movements, more raising the general point that fission power has inherent costs which weren't reflected by narrow 1950s analyses of how much energy was extractable from U-235. Operation of a fission plant requires much more capex and opex than it would if we didn't care about cleanliness (waste management), security (fissile material theft prevention), or safety (meltdown prevention).
Fusion power is more complex to invent and practically depends on modern technologies that didn't exist 50 years ago, but once the first demonstration plants are operational, marginal costs to deploy and operate more should be much lower and ultimately become very low at scale.
> Drilling is one of those things which used to be extremely expensive but has very gradually come down in price. Thanks, ironically, to the oil industry. It's unsexy because there's no "silver bullet" waiting in the wings. It's also quite hard to find suitably hot rocks suitably close to the surface.
That's basically it. Most geothermal plants today are in locations where there are hot rocks, maybe geysers, close to the surface. "Deep geothermal" gets talked about, because temperatures high enough for steam are available almost everywhere if you can drill 3,000 meters down. There are very few wells in the world that deep, not counting horizontal drilling runs.
The economics are iffy. You drill one of the most expensive wells ever drilled, and you get a medium-pressure steam line. Average output is tens of megawatts.[1]
[1] https://pangea.stanford.edu/ERE/db/GeoConf/papers/SGW/2020/A...
The economics change when you’re in oil country. My beautiful little province has oil wells drilled between 250 and 2900 metres. Due to corporate ‘issues’ many of these wells are orphaned and remediation becomes a provincial problem. With deep holes and provincially owned electricity and gas companies, geothermal makes more economic sense; it’s robbing a benefit from a big cost centre.
I went to high school with two guys who are working on geothermal as a means to remediate orphan wells. I’m biased in their favour, but the numbers make a lot of sense.
Plasma drilling is a recent development that looks promising for unlocking deeper wells for geothermal.
Remains to be seen, it has serious trouble with water getting into the borehole.
Many others here have talked about the difficulties of geothermal, which doesn't really get to the heart of my question: why the lack of hype around breaking down those difficulties? I appreciate that you took the time to comment on why it isn't so sexy, the SF argument probably has a lot to do with it.
Why not is explained in David McKay's book Sustainable Energy - without the hot air
https://www.withouthotair.com/c16/page_96.shtml
The problems are that rock isn't a good conductor of heat, so once you've cooled a bit down, you have to wait for it to warm up. Warming only happens very slowly at the rate of < 50mW / m² which limits the amount of power you can get out.
That's a really good point, and it does take the wind out of the sails. Isn't it possible that eventually we could drill deeper?
Couldn't you frac the rock like they do with oil and gas drilling or have a branching borehole?
Yes, that's what this article is about.
Until recently, the geographical locations where geothermal is feasible and economic was very limited. Ironically it is tech from fracking/shale gas that is starting to open up a far wider range of possible sites at lower cost.
There have been numerous trials that had to be stopped because of the triggered earthquakes... Geothermal is not so easy.
Was going to mention that point: http://www.seismo.ethz.ch/en/knowledge/geothermal-energy-ear...
The worst earthquake that was induced that way was 3.5, but given that one of the quakes happened in an area that had a catastrophic earthquake in the Middle Ages, some caution might be warranted: https://en.wikipedia.org/wiki/1356_Basel_earthquake
Harder absolutely but "less likely to be reliable"?
If economically viable fusion was "cracked" what would the nature of it's unreliability even be?
all the machinery used to obtain and maintain an economically viable fusion reaction. Having worked with particle accelerators and synchrotron rings, I'll tell you that stuff breaks down all the time.
The reactor breaking and taking a very long time to repair because the repairs would have to be done remotely, with robots. The structure becomes too activated for people to go inside, even after the reactor is shut off.
The reactor breaks because it's a large device operated at high stresses (power/area, neutron loading). There are many components and joints that can fail.
BTW, this means fusion will be expensive, because getting all those components to be reliable right off the bat becomes expensive. No tiny cracks in the welds means expensive quality control.
Because unless you sit on top of a volcano, amount of renewable geothermal energy is minuscule. In most places on Earth it's somewhere around 40 mW/m2 (i.e. accounting for conversion losses you need to capture heat from ~500 m2 to renewably power one LED light bulb!). In other words, in most places geothermal plant acts more like a limited battery powered by hot rock, so unless drilling is extremely cheap, it does not make economic sense compared to other energy sources.
While it's true that a geothermal plant is a limited battery powered by hot rock, that doesn't mean it doesn't make economic sense compared to other energy sources.
> In most places on Earth it's somewhere around 40 mW/m2 (i.e. accounting for conversion losses you need to capture heat from ~500 m2 to renewably power one LED light bulb!)
Ground-source heat pumps extract about 1000 times more power from ground loops, where does the difference come from?
Ground-source heat pumps are irrelevant to geothermal energy sources, and it's unfortunate that the article mentioned them. Ground-source heat pumps are just storing heat from the air during the summer and retrieving it during the winter.
A number of sources. Often the air above - ground source relies on the ground being the average temperature of the year round air once you get deep. They also tend to run in heating mode half the year, and cooling mode the other half.
I think OP meant technology for drilling becoming cheaper rather than the near-surface availability of it.
I think it mainly depends on how easy it is to access that energy. I went to Tuscany last year and to my surprise there were geothermal plants everywhere. I have never heard about these plants beforehand, but here they are in Italy quietly powering the countryside and heating greenhouses to grow basil all year around.
Probably because not everywhere on earth has the same easy access that Iceland has. The article mentions this:
> There aren’t gates of Hell just anywhere. A kilometre below ground in Kamchatka is considerably hotter than a kilometre below ground in Kansas. There is also readily accessible geothermal energy in Kenya (where it provides almost fifty per cent of the country’s energy), New Zealand (about twenty per cent), and the Philippines (about fifteen per cent)—all volcanic areas along tectonic rifts. But in less Hadean landscapes the costs and uncertainties of drilling deep in search of sufficient heat have curtailed development.
It also explains why this is no longer a problem.
Power flow is in general very low - ca 50-60 mW/sq.m
There is a crazy amount of energy available everywhere but it is not in the interest of the very powerful very wealthy existing players. This isn't some grand CONSPIRACY. For example oil companies may construct energy investment portfolios that would quite sensibly acquire promising energy related research. They do a simple cost benefit analysis then chose to modestly further research it or shelve it. They turn it into valuable pieces of paper that accumulate value over time. What is there for them not to like about it?
I like how David Hamel put it: We live in this thin sliver on the surface of the planet where it is reasonably peaceful. This is the tranquility! It's a good thing! If you go up or down by a mere few miles there is so much energy it kills you.
Instead of drilling deep, there is also an intersting case for storing cheap solar energy as hat in piles of dirts in the summer to power turbines in the winter: https://austinvernon.site/blog/standardthermal.html
The Berlin one also had some promising news today: https://www.adlershof.de/en/news/successful-tests-on-undergr...
We have to see if and when any of them goes into production, but the technology seems very interesting
https://archive.today/CR2KL
Purely as an aside, I had the pleasure of visiting Iceland in August and it was great. Truly beautiful, rugged land.
Another way they've utilised geothermal energy is with large, sophisticated greenhouses which allow growing of many produce they would otherwise import. I only had the opportunity for a brief visit but a lot of it looked hydroponic with really interesting monitoring and control technology. (Plus the biggest bees this Antipodean has ever seen! These suckers were so big they didn't buzz, they rang the doorbell.)
My favorite memory is following a map to a small isolated hot spring off of some random gravel road in the middle of nowhere. It consisted of a hot-tub-sized pool and a shower.
Whoever was there before had left the shower running. We were the only people there, and hadn't seen anyone pass us on the (dead end) road, so it must have been on for quite a while.
Only when I went to for my pre-soak shower did I realize that it didn't actually have any kind of user-accessible way to turn it off.
Iceland's hot water was a culture shock to me in 2 ways:
1. The host at our apartment encouraged us to leave the windows cracked and the heat on for good air circulation.
2. The hot water (at the taps) has a sulfer smell, because it's (also) piped geothermal water. My host explained they also had a water heater upstairs in their home because they preferred "heated cold water" over "hot water", which is a funny distinction to those of us who do not have the latter.
When heating is dirt (heh) cheap, it doesn't cost much to do things like put big hot tubs and heated pools outdoors, like they do in Reykjaviks swim halls. It's really nice.
One of the benefits of over-provisioning solar is that fun "wasteful" things that use a lot of energy become practical and non-harmful.
I was wondering how feasible it would be to reuse abandoned oil pumps for geothermal energy. A closed loop system [1] would probably be the most appropriate, with energy generation by spinning of a turbine by steam that gets recycled. I don't have the expertise and was wondering if someone can share a bit of knowledge with the rest of us.
[1]: https://en.wikipedia.org/wiki/Closed-loop_geothermal
I don't have knowledge, but my understanding based on a conversation I had on the topic with a friend of mine is that the "let's use hydraulic fracturing to make geothermal energy feasible in North America" idea involves drilling very far down. Oil is on [average][1] about a mile down, while [one of Fervo's wells][2] is three times deeper.
[1]: https://www.eia.gov/dnav/ng/ng_enr_welldep_s1_a.htm
[2]: https://fervoenergy.com/fervo-energy-pushes-envelope/
Sorry the time had not come for geothermal. It will always be an expensive niche market. Will there be more? Sure but its ever going to fly globally.
The problem is how do you remove the incumbents. Oil lobby is pretty strong. Imagine what would happen to car lobby once we have teleportation.
There are scifi stories that have that kind of premise. Here's one, about electric power: "Damned if you don't" by Randall Garrett (https://www.gutenberg.org/cache/epub/24064/pg24064-images.ht...). I think there was also one about teleportation, although I can't remember where I read it.
People across the road from have geothermal, driven by a 1.5m-deep pond right near their house. Their heat never costs more than $100 a month in the winter.
That's a different "geothermal" - the correct name is "ground source heat pump" or in your neighbor's case, a pond-source heat pump. Those exploit the temperature stability that occurs some small numbers or meters subsurface for heating in the winter and cooling in the summer.
"Geothermal energy" involves drilling down to hot rock to tap intense heat to run a turbine that produces electricity.
wouldn't it be "natural geothermal" if the pond is a naturally occurring hot spring?
It wouldn't work very well for cooling then
That Newberry Crater one is really close to where I live and... it'd be so amazing if it came to fruition. It sounds almost 'too good to be true'.
Drill baby drill!
Seriously this would be such a dream!
Turns out that the best battery is literally 10 feet away* - and you don't even need to charge it!
*if you want to make steam its a few thousand, but for heating and cooling its literally just 10 feet!
Well, heat pumps are awesome, but ground-source is overkill for many places where the air temps don't fall too low (and it's a lot harder to drill holes behind your house).
I hadn't realized that the IDDP had hit magma! That's very exciting! Obviously I'm very out of date, since that was in 02008.
However, I'm skeptical that geothermal energy can be economically competitive with solar without major innovations in heat engines, no matter how abundant the energy is and how easily you can get that energy to the surface.
https://www.eia.gov/analysis/studies/powerplants/capitalcost... outlines the estimated costs (five years ago) of a 650MW peak ultra-supercritical coal power plant without carbon capture; the total capital cost estimate comes out to US$2.4 billion, which is US$3.70 per peak watt. Of that, I think the only line item that wouldn't be the same in a 650MW peak ultra-supercritical geothermal plant is "Mechanical – Boiler Plant", which is US$905 million, leaving US$1.5 billion, US$2.30 per peak watt. (I'm not even sure you could eliminate even all of that US$905 million in a geothermal plant; some of it might be plumbing you'd also need to pass heat from your downhole heat exchange fluid with the ultra-pure deionized water you use to drive the delicate steam turbine. But let's suppose you could.) Of that US$1.5 billion, US$155.2 million is "Mechanical – Turbine Plant", so the turbine alone costs 24¢/Wp.
But SEIA last year published https://www.seia.org/research-resources/solar-market-insight.... They have a set of cost breakdowns for “turnkey installed price” for power plants, coming in at 98¢ per watt for “utility-scale fixed-tilt”, slightly higher than the previous year and almost half due to about 40¢ for the PV module itself. Residential is at 325¢, with about 20¢ for the PV module. That's even in the US, where the EIA report's estimates were sited, despite the US's prohibitive import tariffs on solar panels from China, which makes most of the world's solar panels.
Mainstream PV modules are now 12.3¢ per peak watt https://www.solarserver.de/photovoltaik-preis-pv-modul-preis... (except in the US), which would drop SEIA's cost estimates from 98¢/Wp to 70¢/Wp, even in the absence of any other cost optimizations in solar farm design.
Now, utility-scale fixed-tilt solar farms typically have a capacity factor of around 20%, depending on latitude, because the sun is below the horizon half the time and somewhat slanted and/or clouded most of the rest of the time, so 70¢/Wp is really about US$3.50 per watt, not counting the batteries. But geothermal typically only has a capacity factor of around 74% in the US https://en.wikipedia.org/wiki/Capacity_factor#Capacity_facto... so US$2.30/Wp is really US$3.10 per watt.
That leaves you 30¢/Wp (74% × ($3.50 - $3.10)) for geothermal exploration and drilling. And if you can reduce the 82% of the solar 70¢/Wp represented by the non-PV-module costs by a little bit, or if you're equatorial enough that your PV capacity factor is 23% or above, that's going to zero or negative. I think the average PV capacity factor in California is something like 29%, though that isn't fixed-tilt and therefore has slightly higher costs.
Also note that the PVXchange page I linked above lists "low-cost" solar panels as having fallen to €0.050/Wp this month, a new historic low, which is 5.9¢/Wp. That's a 50% price decline from two years ago.
Fundamentally I think it's just going to be very hard for 24¢/Wp steam engines to compete against 5.9¢/Wp solar panels. The steam engines have the additional disadvantage that, to get the price even that low, you need enormous degrees of centralization—on the order of a few thousand power plants for the whole population of the US. This requires long-distance electrical transmission lines as well as local distribution lines, which are both substantial costs of their own as well as wasting a double-digit percentage of the energy. Local electrical generation eliminates those costs; you can charge your cellphone or your angle-grinder battery directly from a 5.9¢/Wp solar panel with no more electronics than a couple of protection diodes, not requiring the rest of the 70¢/Wp in the utility-scale solar plant.
This cost analysis is completely indifferent to where the heat to boil the water comes from, so it applies equally well to nuclear power, except for Helion.
The exceptions would be in places where geothermal energy is available and solar energy is either unavailable or very marginal: the surface of Venus, the ocean floor, Antarctica, Svalbard, etc.
Does anyone have a trustworthy estimate of the costs of drilling? Even drilling into cold rocks (for oil) would be a good start, even if hot rocks are more expensive to drill into. The article says that Fervo has raised US$800 million in capital and drilled three appraisal and demonstration wells with it so far, which gives us a ballpark of US$200 million per well. This does not offer much hope that drilling costs will be a minor fraction of the costs of a geothermal plant.
The article unfortunately doesn't enter into this analysis at all.
I am somewhat skeptical of this figure:
> Geothermal energy production in the U.S. at that time [i.e., 02005] was around three or four thousand megawatts.
https://en.wikipedia.org/wiki/Electricity_sector_of_the_Unit... says that geothermal energy production in the US in 02022 was 16.09 billion kWh per year, which is 1825 megawatts. Does that mean that geothermal energy production fell by about half between 02005 and 02022? More likely Rivka Galchen got confused.
It's unfortunate that the article also confuses ground-source heat pumps (thermal energy storage) with geothermal energy sources. It's a common confusion, and it makes conversations about geothermal energy unnecessarily difficult.
It's nuclear fission. It's always been nuclear fission (well, at least since the '50s) and it will continue to be until we commercialize fusion reactors. Everything else is nice to have but it's like NIH syndrome.
Geothermal is fission, and wind, solar, and batteries are fusion at a distance. In both cases, the failure scenarios are benign vs traditional fission generation. It's fine to keep striving for fusion humans control, but the problem (global electrification and transition to low carbon generation) is already solved with the tech we have today. It took the world 68 years to achieve the first 1TW of solar PV. The next 1TW took 2 years. Globally, ~760GW of solar PV is deployed per year (as of this comment), and will at some point hit ~1TW/year of deployment between now and 2030.
Geothermal is a great fit for dispatchable power to replace coal and fossil gas today (where able); batteries are almost cheaper than the cost to ship them, but geothermal would also help solve for seasonal deltas in demand vs supply ("diurnal storage").
https://reneweconomy.com.au/it-took-68-years-for-the-world-t...
https://ember-energy.org/data/2030-global-renewable-target-t...
I also love geothermal for district heating in latitudes that call for it; flooded legacy mines appear to be a potential solution for that use case.
Flooded UK coalmines could provide low-carbon cheap heat 'for generations' - https://news.ycombinator.com/item?id=45860049 - November 2025
Failure scenario in modern fission reactors is also benign. Reactors are designed to lock down to prevent any leaks.
We deploy solar PV capacity, this doesn't mean we actually get that much power from the deployments. Nuclear fission provides reliable, baseload power, and doesn't require huge battery arrays to compensate for the sun setting or winds calming.
Enough renewables are deployed annually to replace the global nuclear fission fleet, year after year, even when accounting for capacity factor derating (to make a like for like comparison). The race is over, and renewables (with batteries) won. If you can find someone unsophisticated to invest in a fission reactor that takes billions of dollars and 10-15 years to build, more power to you. There will be no need for it by 2035-2040 when it prepares to send its first kwh to the grid.
(and to stay on topic for this thread, geothermal is a component of this when geothermal potential exists, cost is competitive, and dispatachability is a requirement to push out fossil generation in concert with renewables, hydro, legacy nuclear, battery storage discharge, and demand response)
https://www.google.com/search?q=baseload+is+a+myth
https://cleantechnica.com/2025/11/15/coal-killing-sodium-ion...
https://ember-energy.org/latest-insights/q3-global-power-rep...
https://ember-energy.org/latest-insights/solar-electricity-e...
https://ember-energy.org/latest-insights/solar-electricity-e...
https://world-nuclear.org/information-library/economic-aspec...
https://www.lazard.com/research-insights/levelized-cost-of-e...
https://ourworldindata.org/grapher/solar-pv-prices
https://ourworldindata.org/battery-price-decline
https://ourworldindata.org/data-insights/solar-panel-prices-...
https://news.ycombinator.com/item?id=44513185 (lfp battery storage cost citation in 2025)
> If you can find someone unsophisticated to invest in a fission reactor that takes billions of dollars and 10-15 years to build
Unsophisticated investors like the Chinese government? 'Nearly every Chinese nuclear project that has entered service since 2010 has achieved construction in 7 years or less.'
https://thebreakthrough.org/issues/energy/chinas-impressive-...
They dabble in nuclear, but it is not their focus. China can do what the developed world cannot because they are a command economy with less expensive labor, which will only last for a bit longer due to their structural demographics. Unless the developed world no longer has labor regulations, developed world wages, and capital based allocation systems, my statement stands with regards to investment. If capital and labor does not matter, certainly, anything is possible (Paraoh demanding pyramids, for example).
Your citation comes from an organization with pro nuclear bias.
https://en.wikipedia.org/wiki/Breakthrough_Institute
Can China Break Nuclear Power’s Cost Curse—and What Can the US Learn? - https://rooseveltinstitute.org/blog/can-china-break-nuclear-... - September 17th, 2025
China built more solar power in the last 8 months than all the nuclear power built in the entire world in the entire history of human civilisation. And even if you adjust for utilisation rate to compare against nuclear utilisation China built more solar power generated per hour than all the nuclear power currently in operation generate in an hour - and did so in 12-18 months - https://bsky.app/profile/climatenews.bsky.social/post/3lggqu... - January 23, 2025
China is installing the wind and solar equivalent of five large nuclear power stations per week - https://www.abc.net.au/news/science/2024-07-16/chinas-renewa... - July 15th, 2024
Nuclear Continues To Lag Far Behind Renewables In China Deployments - https://cleantechnica.com/2024/01/12/nuclear-continues-to-la... - January 12th, 2024
Nuclear Energy & Free Market Capitalism Aren’t Compatible - https://cleantechnica.com/2023/11/06/nuclear-energy-free-mar... - November 6th, 2023
https://x.com/MoreBirths/status/1910780131318374524 | https://archive.today/iu9jx (China demographics citation)
If France–a country known for its strong labour laws and unions–could transition to nuclear in the '70s, any Western country can do it.
Even if the Western world lags behind due to labour regulations, the cost still pays off in the long run due to overall less complex infrastructure and stable, AC baseload power. You are thinking only about the cost of building. What about the cost of maintaining all that infrastructure? Huge solar and wind farms spread out over vast areas, essentially destroying the local ecology? NPPs have a relatively tiny footprint.
Every cited source has a bias. You think 'Clean Technica' is unbiased? Come on.
The options in the '70s were much different from those of today. And for France specifically what they have underground (lots of uranium, no oil, no gas & no coal) strongly suggested exactly one way forward.
Wind and solar existed in the 70s as well.
Plus, Germany invested 500 billion Euros in its energy transition and is STILL heavily dependent on coal.
They’re at ~60% total power from renewables in 2025, and increasing every quarter. I’d say they’re doing pretty well! The coal is unfortunate, but was due to the Ukraine war and gas situation.
> Wind and solar existed in the 70s as well.
This is basically nonsense to the extent that it is becoming difficult to extend the presumption of good faith to you. In the 70s solar panels cost US$25+ per peak watt, in 02021-adjusted dollars: https://en.wikipedia.org/wiki/Solar_energy#/media/File:Solar...
Now they cost 5.9¢ per peak watt: https://www.solarserver.de/photovoltaik-preis-pv-modul-preis...
Installing a gigawatt of solar power generation capacity for US$25 billion is in no way comparable to installing a gigawatt of solar power generation capacity for US$59 million.
Wind power has experienced a similar but less extreme cost decline.
> Wind and solar existed in the 70s as well.
Not really. Solar has gone down in price almost 500X since 1975.
https://ourworldindata.org/grapher/solar-pv-prices
Wind has gone down significantly too.
https://docs.nrel.gov/docs/fy12osti/54526.pdf
Meanwhile, the graph for nuclear waste disposal is going rapidly in the opposite direction.
https://www.ans.org/news/article-6587/us-spent-fuel-liabilit...
http://large.stanford.edu/courses/2024/ph240/kendall1/
> If France–a country known for its strong labour laws and unions–could transition to nuclear in the '70s, any Western country can do it.
France had to nationalize EDF because they could not afford the costs associated with their nuclear fleet. The 70s are 50 years in the past, and are not what the future will look like.
This is also why Spain plans to retire its remaining nuclear generators, and go all in on renewables.
EDF fleet upkeep will cost over 100 billion euros by 2035, court of auditors says - https://www.reuters.com/business/energy/edf-fleet-upkeep-wil... - November 17th, 2025
French utility EDF lifts cost estimate for new reactors to 67 billion euros - Les Echos - https://www.reuters.com/business/energy/french-utility-edf-l... - March 4th, 2024
Explainer-Why a French plan to take full control of EDF is no cure-all - https://www.euronews.com/next/2022/07/07/edf-nationalistion - July 7th, 2022
Spain’s Nuclear Shutdown Set to Test Renewables Success Story - https://www.bloomberg.com/news/articles/2025-04-11/spain-s-n... | https://archive.today/4fB7K - April 11th, 2025 (“Spain is a postcard, a glimpse into the future where you’re not going to need baseload generators from 8am to 5pm” with solar and wind providing all of the grid’s needs during that time, said Kesavarthiniy Savarimuthu, a European power markets analyst with BloombergNEF. Still, she said, there is a reasonable chance this goal may take longer than expected and “extending the life of the nuclear fleet can prove as an insurance for these delays.”) (My note: As of this comment, Spain has 7.12GW of nuclear generation capacity per ree.es, and assuming ~1GW/month deployment rate seen in Germany, could replace this capacity with solar and batteries in ~28-36 months; per Electricity Maps, only 17.25% of Spain's electrical generation over the last twelve months has been sourced from this nuclear)
Tangentially, Europe has enough wind potential to power the world, for scale.
»Your citation comes from an organization with pro nuclear bias.«
Go and throw all your money into renewables stocks and ETFs if you’re so convinced.
I bet you’re not doing that because you realize that the industry isn’t doing well and it’s nuclear power nowadays where all the money goes.
Personally, I've invested ~500k EUR in a Portuguese Golden Visa fund invested in renewables (IRR is ~7-13%). Macro speaking, renewables investments keep hitting new records. I am convinced, and if you are not, I would strongly suggest consuming more data, because you appear to have a potential blind spot in your mental model on this topic.
https://about.bnef.com/insights/clean-energy/global-renewabl...
https://www.bloomberg.com/opinion/articles/2025-10-28/white-...
»Enough renewables are deployed annually to replace the global nuclear fission fleet, year after year, even when accounting for capacity factor derating (to make a like for like comparison).«
Wind and solar do not replace conventional power plants and never will.
Heck, Germany tried that on the small island of Pellworm and failed and yet some people think this will work out for the whole country.
It does not work.
Nuclear is great, but it does require wheelbarrows of cash, and we don’t have a solution for waste products.
Things are more expensive when we keep reinventing the wheel and trying to do new things instead of just reusing proven designs. Remember that solar power also used to cost wheelbarrows of cash back in the day. When you do something repeatedly, it becomes less expensive over time.
Nuclear is actually the leader in waste management. No other energy source has as complete a story. Eg what happens to solar panels when they EOL in 25 years? They go into landfills and leach toxic chemicals into the ground. These chemicals, like lead and cadmium are toxic forever. They have no 'half-life' in which their toxicity reduces.
Solar panels do not become useless in 25 years and need to be discarded, do not leach toxic chemicals, and do not contain cadmium. They do contain small amounts of lead, but leaching metallic lead out of landfills is very difficult and probably does not ever happen unintentionally.
A nuclear plant about 50 miles from my house was closed 15 years ago. The spent fuel rods will be stored there indefinitely until a federal facility is built.
Solar panels are recycled at almost 100% of total materials. Redwood Materials (founded by Tesla's former CTO) has already established a supply chain to ingest and recycle EV and stationary storage batteries at scale. The problem is that the hardware is lasting longer than expected, and meaningful recycling volume does not yet exist.
Conversely, ~95,000 metric tons of nuclear waste in the US does not have permanent storage or recycling solutions, as of this comment, and there is no plan for long term storage or recycling. Nuclear generation is experiencing a negative learning curve; we keep spending more the more we attempt to build it.
(solar PV panels have a 25-30 year service life, at which point they will still produce power at ~80-85% initial rating, batteries have a 15-20 year service life, with sodium ion chemistries estimated to have up to 50 year service life assuming once daily cycling)
https://www.epa.gov/hw/solar-panel-recycling
https://www.energy.gov/eere/solar/articles/beyond-recycling-...
https://e360.yale.edu/features/solar-energy-panels-recycling
https://www.cnbc.com/2025/11/09/nuclear-power-energy-radioac...
https://www.gao.gov/nuclear-waste-disposal
https://decarbonization.visualcapitalist.com/visualizing-all...
(nuclear power accounts for about 10% of electricity generation globally, as of this comment)
> Solar panels are recycled at almost 100% of total materials.
That's very clever wording. If someone glances at this sentence they might interpret it to mean that almost all solar panels are recycled. But your own citation tells a different story: https://e360.yale.edu/features/solar-energy-panels-recycling
> Today, roughly 90 percent of panels in the U.S. that have lost their efficiency due to age, or that are defective, end up in landfills because that option costs a fraction of recycling them.
Let's compare to spent nuclear fuel, which we know for sure does not end up in landfills. I am talking about today, not some hypothetical utopian future. Today, NPP spent fuel is safely sequestered while solar panels are dumped into landfills.
> nuclear waste in the US does not have permanent storage or recycling solutions
It does, it's just not built yet because it doesn't make sense to do it now. In a few decades, maybe a century we will have commercialized fusion reactors. Once we do, we switch to fusion completely and build the deep geological repositories or whatever other solution makes sense then. Or we can even recycle the spent fuel–the only thing stopping us from doing that now is misguided US politics (as usual).
> we keep spending more the more we attempt to build it.
It's capex. We are investing in nuclear technology. If you have a proven design and build the reactors at scale, the costs will flatten or decline, which is obvious to anyone who knows about economies of scale.
Look at Electricity Maps and realize that France is the only large industrial country where electricity generation is permanently carbon-free and cheap.
https://particulier.edf.fr/content/dam/2-Actifs/Documents/Of...
Yes, but unfortunately that is because it is coasting on decades old labor and capital investment that will not be made again. It is not permanent, as it will cost tens of billions of euros to continue to operate those generators reaching the end of their service life.
Norway, Iceland and British Columbia are other examples and are more carbon-free than France is. The latter isn't a country and the former don't count as "large industrial"?
Solar + wind is being installed at about 100x the rate of fission because it's so expensive. And the differential is only increasing.
installs: https://www.pv-magazine.com/2025/01/13/the-fastest-energy-ch...
costs: https://www.reddit.com/r/energy/comments/11q58pe/price_trend...
It could be but the US and EU have so far been unable to build commercial fission reactors without going 2x+ over budget in time and money. China is having success but even they are not projected to have nuclear account for more than single digit percentages of their generation.
Maybe SMR's, thorium, 4th gen, etc will work out, but maybe not.
»It could be but the US and EU have so far been unable to build commercial fission reactors without going 2x+ over budget in time and money.«
The EU also forgot how to build airports and train stations on budget and on time.
Should we stop building airports and train stations?
As for nuclear power plants: Germany and France built most of their reactors on budget and on time.
50+ years ago, not relevant.
The US Navy consistently builds reactors on-time and in-budget
The US and Russian Navies deciding to remain mostly petroleum-fueled is one of the strongest arguments against nuclear becoming very cheap: surely they would do it if it wasn't ruinously expensive, because it eliminates the national security risk of a petroleum blockade and simplifies at-sea logistics immediately.
There’s something to be said for a standardised design with replaceable parts.
Ive been very pro nuclear my whole life, but a part of me is disheartened by the mega projects that commercial fission deployments have become (even if the reasons are bad) that’s a problem that nerfs traditional fission. If nuclear remains both political, extremely bureaucratic and requires public investment, it just won’t be the solution, and not because the tech or physics is bad, but the decision makers & investors can no longer organize large infrastructure projects effectively (except maybe China). This is not unique to nuclear.
Having smaller scale local power generation, whether it’s SMRs, solar, wind or geothermal, there’s a huge advantage in terms of economy, investment, and politics.
Nuclear has broad bipartisan support, and the Trump administration is heavily into it, so I wouldn't count it out just yet. If the various Green parties of the Western world ever come into power though, we are cooked.
But that illustrates the point. Most investors don’t want to put money towards something that may be put on indefinite hold depending on political winds. These projects are often much longer than presidential terms.
It always has been. Our problem is switching over existing infrastructure without asinine complainers ruining the revolution. We can't even declare total victory with LED bulbs over incandescent. The war to have solar plants over more coal is falling back to coal thanks mostly to AI. Pushback on geothermal will arrive, I guarantee it.
> We can't even declare total victory with LED bulbs over incandescent.
The LED bulbs I have access to (whatever's in the aisles at Home Depot, Costco, etc.) fail much more frequently than the incandescent bulbs I used to buy, and produce an uglier light that is less warm even on the softest/warmest color settings.
My suspicion is that incandescents were at the "end" of their product lifecycle (high quality available for cheap) and LEDs are nearing the middle (medium quality available for cheap), and that I should buy more expensive LED bulbs, but I still think that there are valid "complaints" against the state of widespread LED lighting. I hope these complaints become invalid within a decade, but for now I still miss the experience of buildings lit by incandescent light.
The other thing with AI--the LED revolution was led on this idea that we all need to work as hard as we can to save energy, but now apparently with AI that's no longer the case, and while I understand that this is just due to which political cabals have control of the regulatory machinery at any given time, it's still frustrating.
In many cases you can break one of the resistors off the LED bulb's printed-circuit board and run them at two-thirds of the power so they last forever. In other cases the surgery required is a little more involved than just snapping a surface-mount resistor off with pliers.
None of this will change the CRI.
> uglier light that is less warm
I figured out why this happens.
The light color they call "daytime" is around 5000K, so I expected it to look like being outside in the sun; but instead I got a cold blueish vibe. The problem? Not enough power! I got the equivalent of a moonlit room.
So I got this 180W LED lamp (that's actual 180W, not 180W equivalent) [1]. It's so bright I couldn't see for 5 minutes. I put two in my office on desk lamps. The room now looks like being outside, without the "ugly blue" tint, even though the product says it's 6000K. The days of my SAD suffering are over!
[1] https://www.amazon.com/dp/B0962X573M
> The LED bulbs I have access to (whatever's in the aisles at Home Depot, Costco, etc.) fail much more frequently than the incandescent bulbs I used to buy, and produce an uglier light that is less warm even on the softest/warmest color settings.
LED lamps work just fine, you just need to pay more attention when you’re buying them. Philips makes decent LED lamps.
Make sure you’re buying lamps with 90+ CRI, that will help with the quality of light. 2700K is a good color temp for indoor living room/dining room/bedroom lighting, 3500-4000K for kitchen/garage/task lighting.
You also need to buy special lamps if you put them in an enclosed fixture, look for ‘enclosed fixture’ rated lamps. Regular LED lamps will overheat in an enclosed fixture.
Yup - CRI is most important. Indoor house plants also like high CRI lights much more as well!
I think houseplants will like horticultural LEDs much more than high-CRI lights.
Maybe buy your bulbs somewhere else? I'm yet to replace any of the LED bulbs I've bought over the past 15 years and honestly can't even remember the last time a bulb failed.
Mine fail all the time. Cheap Amazon Basics, expensive Phillips.
Do they fail more than incandescents? idk maybe not, but they fail much more often than their advertising would suggest.
Actually, since posting this I've vaguely remembered a previous discussion on here about differences between LED bulbs sold in the US and those sold in UK/EU so maybe that explains it.
[CITATION NEEDED] They do not. If you take the mean, median, and mode of the failure lifetime for LED bulbs sold at these stores and compare them to the failure times of incandescent bulbs, I also guarantee you are empirically wrong here.
I believe this is true for the LED technology compared to the incandescent technology as a whole, but I'm simply turning over bulbs at a far higher rate than I did in the incandescent days. Often the LED bulbs are failing within a year under normal usage patterns. It's possible that using modern LEDs in old fixtures is causing some kind of issue.
Are your LED lamps failing in enclosed fixtures? You need to buy special lamps for enclosed fixtures, regular LED lamps will heat up too much for enclosed fixtures.
Look for ‘enclosed fixture rated’ LED lamps for enclosed fixtures.
> falling back to coal thanks mostly to AI
citation needed
There is an enormous push to build and power data centers in the DC / Northern Virginia region, and there's legislation in West Virginia right now requiring all coal-fired power plants to operate at at least 69% capacity at all times to support it.
> “West Virginia has numerous coal plants that have powered this country for decades. We need these plants to remain operational,” [WV Governor] Morrisey said. “… We will never turn our backs on our existing coal plants and we will work with the federal government to pursue new coal-fired generation.”
https://westvirginiawatch.com/2025/09/11/morrisey-shares-new...
https://wvpublic.org/story/energy-environment/data-center-bi...
https://www.wvlegislature.gov/Bill_Status/bills_text.cfm?bil...
The only way new coal plants get built from today on is with massive lifetime subsidies, because they are uncompetitive. Ie, if they get built it’s for dumb politics not economics
That sounds like they want to subsidize the coal industry. AI is just the excuse.
https://fortune.com/2025/08/31/ai-data-center-boom-old-coal-...
> The war to have solar plants over more coal is falling back to coal thanks mostly to AI.
Also, due to solar not panning out at scale.[1]
More seriously, coal is just cheaper and, with incentives being removed for green energy, it's the cheapest and fastest option to deploy. It's dead simple and well understood reliable power.
[1]https://apnews.com/article/california-solar-energy-ivanpah-b...
Wild take. New coal is not cheaper. There have been no new coal plants built in the US since 2013.
That solar plant you linked is an obsolete experimental technology. Obsolete because regular PV became so much cheaper.
> New coal is not cheaper.
I see yow it can read that way but it isn't what I said. Coal plants exist, either shuttered or running low loads due to financial incentives (not favoring them).
Studies show solar is cheaper but businesses continue to choose coal. I think the entity who's entire existence depends on them making the correct financial choice is a much better indicator of economic reality than a study made by people who have zero stake (at best) in the game.
I'm all for green energy but I also don't think people are stupid.
The example you chose is of a mirror based Solar system, which yes, is an obsolete technology.
Direct solar continues to be installed at greater amounts every year and coal is economically uncompetitive with basic anything (which is why it is collapsing), and especially against natural gas.
You're exactly right and it raises a question for me. Why do energy generation topics bring people out of the woodworks who cite some very idiosycratic one-off and use it to make out-of-proportion declarations about the utility of a given technology? This is the second one I've seen suggesting solar is doomed when they mean mirrors.
On twitter I saw someone claim PV is useless for heat because non-PV solar water heating is just so much more efficient. Not even true (I think it's a approximately a wash, different advantages in different applications), but very strangely in the weeds on a specific topic. Much too narrow a factual context to substantiate general level claims about solar as an energy writ large.
I think for whatever reason the missing the forest for the trees trap is really potent in energy discussions.
> Why do energy generation topics bring people out of the woodworks who cite some very idiosycratic one-off and use it to make out-of-proportion declarations about the utility of a given technology?
They either have only read propaganda pieces from fossil fuel producers or are trying to create some of those.
I would expect the number of people that honestly don't know anything but propaganda to be way higher than the number of people creating propaganda. But there's probably a selection bias due to HN being a somewhat large site with some influence on SEO and AI training.
I brought up the mirror plant because the molten salt crucible is an example of an attempt to make solar work after hours. It wasn't viable.
Solar+storage is not a solved problem. The storage problem gets continually hand waived away in the conversations about how cheap solar is.
As I said in a sibling comment, I don't think the people running energy companies are stupid. If solar really was cheaper as a baseline power supply, what it needs to be to replace fossil fuels, they'd be doing it.
> If solar really was cheaper as a baseline power supply, what it needs to be to replace fossil fuels, they'd be doing it.
So, you haven't looked at what energy companies are doing for the last 3 years...
at some point we will figure out that because we took some much energy out of earths core that it stops spinning and causes the magnetic field to collapse ;-)
They've already made a move about that. https://www.imdb.com/title/tt0298814/
Not really how that works. Also earths core is being heated from nuclear decay and tidal effects. It’s getting 10’s or TW worth of heat until the sun expands and eats the earth. https://en.wikipedia.org/wiki/Earth's_internal_heat_budget
The world's total energy consumption (most of which is fossil fuels) is currently estimated at 620 exajoules, or 17TWh / year.
Assuming zero growth in energy consumption (hello AI), extracting even half of that seems like it would be consequential.
10 TW * 1 year = 8,760 TWh / year. The current rate of energy production is ~42TW and slowly dropping over billions of years, so even after efficiency losses gathering 1% of what’s produced is several times current energy consumption.
I believe this is off by 5 or 6 orders of magnitude.
Looks like it's more like 200,000Twh / Yr
https://ourworldindata.org/energy-production-consumption
Thanks for that wikipedia link, it's fascinating!
I think they meant that as a joke.