Nothing good can come of this.
Microsoft needs to start asking if it should do something before it does it.
This is a good way to force the (often monopolistic) providers to get their shit together, as google did with google fiber.
Capitalism fails very quickly the moment you try and push past sensible regulation and legislation. Look at the whole US situation right now.
It's expensive as hell already and we still don't handle waste or environmental issues properly. Capitalism isn't going to solve anything other than the price as it'll defer the rest until it's someone else's problem much like it does not on every single damn sector's waste.
I'm not anti-nuclear. We need it. What we don't need is tech companies getting into the market.
We should assume they're acting rationally, so the real question is, why do they find this interesting at all? Why not dump the money into private solar farms instead?
Gates in particular seems to have been a disciple of Vaclav Smil, a person whose arguments against renewable cost reduction were wildly mistaken.
My understanding was that very little radioactive waste was created from a fusion reactor and what little there is will decay pretty quickly (decades).
I expect that the longevity of their attention is considerably less than this, particularly if the LLM boom crashes. ROI will not pay for the disposal later down the line.
To show the scale of the problem: if the world were powered by Helion's reactors (for all primary energy), and the tritium produced were just released into the environment and mixed completely with all water on the planet (including oceans, lakes, rivers, ground water, and ice), then it would lift all that water above the US regulatory limit for tritium in drinking water. All the water, including everything in every ocean.
So the quantity of radioactive waste will certainly not be little, but more likely much greater than in a fission reactor.
Nevertheless, because there is more freedom in the design of the neutron shield than in a fission reactor, it is likely that it is possible to find such compositions where most of the radioactive waste will decay quickly enough, so that there will remain only a small quantity of long-lived radioactive waste.
However, until someone demonstrates this in reality, it is still uncertain how much radioactive waste will be generated, because this depends on many constructive details.
A lot of components of a fusion reactor, e.g. pipes for cooling fluid and the like, will become damaged by the neutrons and they will have to be replaced periodically, after becoming radioactive. The amount of such waste will depend a lot on the lifetimes of such components. For now it is very uncertain how much time such components will resist before requiring maintenance.
Do they? I hope they don't. I would enjoy seeing MSFT implode and losing trust of its shareholders with its cash - itll be forced to return it rather than reinvest.
Yeah. Countries around the world, including China are abandoning their solar and wind plans and picking up on new nuclear plants instead. Not.
It is a conspiracy I think.
They’re not. The targets keeps being revised down and pushed into the future for every plan they make.
> This was followed by a period of delay as China undertook a comprehensive review of nuclear safety in the aftermath of the Fukushima nuclear disaster.
> Subsequently, moderated nuclear energy targets were established, aiming for a nuclear energy contribution of 15% of China’s total electricity generation by 2035, 20-25% by 2050 and 45% in the second half of the century.
> However by 2023 it was becoming clear that China’s nuclear construction program was well behind schedule. The target for 2020 had not been achieved, and targets for subsequent 5-year plans were unlikely to be achieved.
> In September 2023 the China Nuclear Energy Association (CNEA) reported that China was now aiming to achieve a nuclear energy contribution of 10% by 2035, increasing to around 18% by 2060.
https://reneweconomy.com.au/chinas-quiet-energy-revolution-t...
China has also revamped the funding model for nuclear power with it now having to compete on costs with alternative generation. They have an enormous backlog of reactors which has achieved regulatory approval but have yet to start construction.
In 2025 only 4 reactors have so far started construction, in 2024 the total number was 6 reactors.
At current expansion rates nuclear power's slice of the Chinese grid is shrinking. Let alone multiplying.
Current construction / execution issues involves in dealing with 1st wave of indigenous plants, again it's shrinking as % of grid/mix because denominator is higher than expected, which is independent of central gov desire to multiply nuclear build rate, which they can't reliably commit to until tech is mature. So the best we can say is they're a few years off their planned nuclear GWs and if tech matures, they can go forth and multiply. Of course if alternative LCOE makes nuclear not economical that could change, i.e. if storage blows up. But there's no actual policy hints that nuclear is being revised down, as in not in the last 15 years, which even then is mostly target being pushed a decade due to factors listed. Now they're on trend and the delays are single digit year execution related, not 10+ year we have to rebuild the tech stack delays.
saying "Milestone keeps Helion on track to deliver electricity from fusion to Microsoft by 2028"
but as you say they don't seem to have produced any energy and after watching Sabine's take I'm very skeptical (https://youtu.be/YxuPkDOuiM4)
I think it may be a bit of a scam where they keep the investment and their jobs going as long as possible but don't produce power.
There may be some of that, but I think a lot of it is people who believe in what they're doing. A good example in another field is Stockton Rush and his submarine - assuming he wasn't suicidal, he clearly believed in what he was doing, even though to any sane and informed outsider it was fundamentally and life-threateningly flawed.
"Breaking ground" and "wanting to be first" makes no difference to the physics, engineering, and economics involved here. They're just going to end up with an expensive plant that eats money.
No-one has yet demonstrated a break-even fusion reactor purely from a physics perspective - let alone an engineering or, even more challenging, an economics perspective. In other words, we're essentially still in the fundamental physical research phase.
It's like building international airports for jet planes when you've just invented the Kitty Hawk - but worse, really, because at least the Kitty Hawk proved we could fly in practice. With fusion, there's no evidence that we'll ever be able to create a sustained, economically viable reaction.
What has not yet been shown (and may be impossible?) is fusion working at small scale and over long timeframes.
Fuck's sake, it's just some hot rocks boiling a kettle, we make it out to sound like it's magic but we had the technology for this ~80 years ago. By now we should have the cost of a standard issue nuclear plant down to way cheaper than anything else. Common layout, protocols, processes, software at all of them... could have been complete in 1989, honestly.
If you want "hot rocks", it's probably much cheaper to just resistively heat them with cheap solar (you don't even need inverters). This could store energy over many months and, pushed to its cost reduction limits this promises to be the final nail in the coffin for any dreams of a nuclear revival.
I am imagining a field of shipping-container sized units, each of which is a small modular reactor. Probably with solar panels on top ;) Still a few orders of magnitude different, but the idea here is that each unit is small enough that it can be manufactured, so that nuclear plant bring-ups don't take 30 years. Most of the cost is because of the tremendous generational effort involved in just a single project; what does it take to reduce the cost of the plants themselves to the point where they can really shine, economically?
The goal is to have reliable base load power generation so that we don't have to deal with the massive complexity and carbon footprint of battery plants all over the place to deal with peaky generation technologies like solar. I don't believe that that is a solved problem: using tremendous amounts of rare earth materials for limited-lifespan installations that don't even produce energy is possibly not the best use of our resources, considering it's almost all fossil fuel going into those logistics operations anyway, right? EROEI for a battery plant is going to be hard to achieve.
I think you are onto something. But this requires upfront investment, which alas, politicians are not for.
Because the level of permitted development without being crushed by onerous regulatory burdens has been absurdly hamstrung on nuclear. All of the issues you add as "but" cases are things that many different innovations in a fluid market for research could have refined. The same has been done for many complex technologies over the decades, yet for nuclear there's always some excuse like the ones you mention. The comment you replied to is right. We're talking about something that since decades ago could have been improved enormously, and hasn't been thanks to a multitude of stupidities.
The United States Navy trusts extremely compact reactors (designed and working despite the DoD's notoriously lax financial and schedule stringency with defense contractors) to power its absolute most important, costly, defense-crucial war machines, and regularly docks them right inside the country's (and world's) largest urban areas, but somehow there's just no way to make nuclear power for civilian use more compact, cheaper and effective?
Long term storage and diurnal storage are complementary technologies, sort of like the different levels of cache and main memory in a computer memory hierarchy. Combining them appropriately reduces cost vs. using just one of them.
Anyway, the technology as described would produce heat at 600 C for as little as $3/GJ, which nuclear would have a hard time competing with.
But the key is speed. If you tie up $20B for 20 years uselessly, there's no way you can make a profit on anything.
If we wanted to do SMRs right, the goal should be to build one or more SMR production factories, here in Canada, where we manufacture N reactors per month, that fit onto train cars, and can be delivered to qualified, secure sites around the world. Instead, we're paying massive cash out to GE Hitachi, and so the end result will never be "the capability of building and deploying SMRs", it will be "4 unprofitable SMRs in a facility and $4.4 billion a unit if we want more of them to lose money on".
Obviously this is doomed to fail; the units should cost like $100M max so they have positive ROI within a few years. If the unit will never beat solar in $/megawatt for operating and fueling costs, and won't pay for its own construction cost before its lifetime ends, it should never have been constructed; the entire thing is catabolic, all of the work and carbon that goes into it is an utter waste. Everyone involved should just do something else with their lives if we're going to approach it this way.
What's the point? Why do such small-minded people get authority over grand projects?
The gross thing is seeing the public cheer it on.
I'm intensely pro nuclear. But the tech is still in the stables. We need research into driving down costs. In the meantime, we need to think harder about where we're putting datacentres and how we can, if not make power cheaper for average Americans, at least not raise its real cost.
And while I personally hope we have economical commercial power generation in the future, I'm not convinced that'll ever happen due to one massive problem: energy loss from high-energy neutrons, which have the added problem that they destroy your very expensive containment vessel. Stars deal with this by being massive, having fusion happen in the core (depending on the size of the star) and gravity, none of which is applicable to a fusion reactor.
I'm reminded of the push recycling of plastic. Evidence has surface that this was nothing more than oil industry propaganda to sell more plastic [2]. A lot of "recycling" is simply dumping the problem into developing countries and then just looking the other way. We used to do this to China until they stopped taking plastic to "recycle".
I can't help but think that Microsoft issuing some press releases about nuclear is nothing more than marketing to contributing to the data center explosion that will inevitably drive up your electricity bills because you'll pay for the infrastructure that needs to be built and will be paying the generous (and usually secret) subsidies these data centers engotiate.
[1]: https://blog.ucs.org/edwin-lyman/five-things-the-nuclear-bro...
[2]: https://www.npr.org/2020/09/11/897692090/how-big-oil-misled-...
That's just one of many massive problems? You touched on the reason for this:
> Stars deal with this by being massive, having fusion happen in the core ... and gravity, none of which is applicable to a fusion reactor.
As a result of this, we actually have no good reason to believe that commercially viable fusion power could ever be possible.
While we can create conditions comparable in relevant ways to the core of a star, it's extremely uneconomic to do so, for obvious reasons.
And we haven't even achieved the scientific breakeven point for a sustained reaction, let alone one that remotely approaches being viable from an engineering or economic perspective.
Neutron energy loss would be a good problem to have, because it'd mean we're much further along than we are now. The fact that, after half a century and enormous expenditures, we haven't even reached the point where neutron energy loss is the main problem, gives an idea of just how unrealistic this all is.
You could for example look at China, a country that has embraced nuclear and solar and wind and batteries and EVs because they don't have good access to oil and don't have much government influence from that group.
Do they recycle more or less of their plastic waste than the USA?
Google suggests in 2023 it's 30% in China vs 12% in the USA.
It's a confusing topic, as some anti-plastic campaigners seize on this intentional failure of the US to recycle more and better to try to push total plastic bans.
Which are good policy for specific items, and again we see these being done in China too, as a complement to recycling, not a replacement.
I would have linked it here but none of the search engines are turning up anything at all, and in fact I don't think it's even possible to find stuff like that with search engines anyore.
https://groups.google.com/g/rec.humor.funny/c/4zIyBq1-1_E/m/...
NVidia is worth more than Germany.
Ah, where did that carefree time go, where we had the time to read licenses...
Molten salt reactors, micro-reactors, modularity. It's the miltech we had in the 60s, on the path to commercialization and commoditization.
It's all proven technology and the obvious exemplar is the nuclear-powered navies, micro-cities that can roam, submerged within the depths of, or riding atop the world's oceans, for decades at a time. We've been doing this for over 70 years.
It's only a matter of time. AWS has a campus in PA already next to the power plant at Susquehanna, plugged in. They're invested in small modular reactors.
Google has contracts and investments toward the same end. This fits the pattern we're seeing across big tech, and it's driven by the non-negotiable power demands of AI.
I don't balk at the climate-changists, I'm more curious about the anti-Nuke sentiments on HN; what am I missing?
You are at a much higher risk of dying from a commercial airliner crash in your lifetime than you are of any nuclear operation - accidental disaster or normal operation. There have been zero (0) human deaths in the US from any operation or accident at a nuclear plant. There were zero human deaths from radiation at the Fukushima meltdown. In fact, more than 2,000 people died from the evacuation alone; the earthquake and tsunami killed 15x as many.
Nuclear power is safe. Carbon-friendly. Effective. Operationalized. Not scary, just malunderstood.
I call absolute bullshit on this line of thinking. Microsoft and other corporations have just as much if not more public interest in keeping their reactors safe and effective. Not to mention financial interests.
[1] The video of the debate itself.
I thought solar won.
[0] https://www.astralcodexten.com/p/notes-from-the-progress-stu...
At this conference for progress nerds, with big arguments between solar and fission nuclear "no one wanted to defend fusion".
> Fusion promises cheap clean limitless power if only we can solve difficult technological hurdles. But we already know how to produce cheap clean limitless power. The only delay is regulatory, and fusion doesn’t solve this.
...
> the only pro-fusion sentiment I saw at the conference was a series of graphs comparing “fission” and “fusion” and showing strong performance advantages for ”fusion” in all categories. But it turned out the pro-solar faction had mischievously labeled solar as “fusion” since it ultimately comes from the sun’s solar core. It was a good trick - think of solar as a new high-tech wonder, instead of as the annoying thing environmentalists keep nagging us about, and it really does look like a miracle.
> It's all proven technology
Literally none of the things you mentioned exist at commercial scale. It is the opposite of "proven". This technology is purely hypothetical.
https://world-nuclear.org/information-library/non-power-nucl...
https://www.energy.gov/ne/articles/us-sets-targets-triple-nu...
Certainly the nuclear industry hasn't done themselves any favors either.
https://www.reddit.com/r/EconomyCharts/comments/1l5h5e2/sola...
Nuclear may be a big part of the future (assuming storage prices don't plummet) but it's not going to be the bulk of the power we ever receive. It'll be the 10% that stabilizes the grid and provides baseload, at most.
The numbers from published analyses are clear. The revealed preferences from local market participants and foreign geopolitical rivals strongly aligns with these analyses.
If Bill Gates wants to put his money into making it cheaper per Wh, then that's great, and I support him doing this.
There. No more silly anti nuke gotcha. You can give up on that one permanently.
In the long run solar power will kill fossil fuels, but we desperately need a bridge to get us there and not destroy the carbon balance in the atmosphere. Nuke is that bridge.
Or overbuild renewables reducing the seasonal variations. In cost terms when compared to nuclear power those would be insignificant.
With fossil based energy systems we didn’t match production capacity to consumption 100% with peakers having low capacity factors.
But somehow we can’t overbuild a kWh and need massive seasonal storage when it comes to renewables.
Define "expensive". Over what timescale? Have you seen https://ember-energy.org/latest-insights/solar-electricity-e...
"Achieving 97% of the way to 24/365 solar in very sunny regions is now affordable at as low as $104/MWh, cheaper than coal and nuclear and 22% less than a year earlier."
This is right now, July 2025. The costs of batteries continue to fall. How much cheaper will batteries be by the time we start churning out SMRs fast and cheap?
By all means keep beavering away at nuclear. Its time will come one day. But I won't hold my breath for it to solve the climate problem in the next 10 years.
Storage could get there, but I don’t think it’s credible that manufacturing scale alone will solve the problem. We probably need some new, qualitatively different chemistries to become viable for solar to be viable for the whole grid. From a technical perspective the nuclear plants we could build in the 1960s could do it, whether we can still build them (no matter if the barrier is regulatory or practical) is another question.
How will you get me with rooftop solar and a home battery to buy your extremely expensive nuclear powered electricity when I have my own imperfect solution almost the entire year?
Scale this up to a society adding onshore and offshore wind and you quickly realize that the nuclear plant will have a capacity factor at 10% or so.
Vogtle with a 20% capacity factor costs somewhere like 85 cents per kWh, or $850 per MWh.
Nuclear power due to the massive CAPEX is the worse solution imaginable to fix renewable shortcomings.
Take a look at France. They generally export quite large amounts of electricity. But whenever a cold spell hits that export flow is reversed to imports and they have to start up local fossil gas and coal based production.
What they have done is that they have outsourced the management of their grid to their neighbors and rely on 35 GW of fossil based electricity production both inside France and their neighbors grids. Because their nuclear power produces too much when no one wants the electricity and too little when it is actually needed.
Their neighbors are able to both absorb the cold spell which very likely hits them as well, their own grid as the French exports stops and they start exporting to France.
No.
So its easy, at least if it wasn't for all that burdensome regulation. But also the burdensome regulations is actually good, presumably because it's hard to get right.
This sounds like nonsense to me. If the regulation is good, that would usually be because a thing is hard to make work in a liberal society, usually for some misaligned incentive reasons. In that case the regulation isn't "burdensome" but necessary to counteract the failure of the market.
For say an AI training-oriented data center, you could scale down the power usage when supply is limited. You could change power limits on the CPU/GPUs, put the machines in sleep mode or powered off entirely. So the required storage would just be a slightly bigger UPS.
Not sure if the economics works out, but at least technically it's possible as it's more flexible than user-based loads.
The problem with nuclear energy is not the availability or the cost of the fuel but the capital cost of the reactor and the high level of financial and operational risk involved with the construction. For instance there is an unlimited amount of handwringing over a closed fuel cycle costing a little more than an open fuel cycle but nobody points out that the capital cost of the reactor dwarfs fuel cycle costs for any fuel cycle -- no nukes hate reprocessing so they won't point this out and nukes don't want to remind you of the capital cost problem.
For every NPP that's had a nuclear meltdown there have been 20 that had a financial meltdown before they've even turned it on.
It drives me up the wall that big tech companies want to buy "a reactor" or an unspecified "SMR" but never an AP1000 (reactor that's actually been built) or even a BWRX300 (an SMR that might actually get built.) If there wasn't any bullshit a new build AP1000 would probably have a 10 year lag at least but...
... in the current international tariff situation it's almost impossible that any full-size or even moderate-sized reactor will be built in the US in the forseeable future because the US has no super-heavy press that can forge a nuclear reactor vessel. Japan, China, Korea, the UK, and many other countries have them and in the neoliberal world of a year ago we could have just had one made for us and shipped in by boat. The BWRX300 is the only western SMR that is far along and the pressure vessel will be made in Canada -- it's going to cost plenty no matter what but put 35% on top of that and you're doing the no nukes job for them. Way to go.
I want to see it work but I am not seeing realistic plans from the likes of Microsoft and Google, just the hot air from a 100W lightbulb when we really need 10,000,000 times as much heat!
Yes, in US and western Europe it's been practically impossible to build new reactors since the 90's for capex and regulatory reasons (both are related). However, we used to be able to build reactors significantly cheaper and faster and I'd argue we're on the path to do it again later this decade. There's no technical reason we can't solve this problem: there's bipartisan support for nuclear, willing financial backers, and no demand shortage. We're going to see 100+ gigawatts of new nuclear in the western world in the next 20 years.
I've looked long and hard and not found an explanation of the bungling fitting the facts better than that it's like a poker game: the vendor never believed in the sticker price, but the vendors figured that once there were chips in the pot the sunk cost fallacy would mean the buyers would never fold.
Thing is, they do, at least in the U.S.
https://en.wikipedia.org/wiki/Nukegate_scandal
I think NuScale was trying to be honest about costs but the buyer in Utah built a process in which they could control costs by folding early and they did. Europe, China, and other places have more engineering thinking and less financialization and they're more likely to "stay the course" but as an engineer I'm not sure this is right -- it might work for China but not for Europe.
On one hand I'm glad to see GE get the BWR, especially the work done on ESBWR, back into the game with the BWRX300, but the costs they are quoting are too freaky low and their talk about "design to cost" makes it seem like they just quote the cost number that they need to be competitive with the solar sticker price without storage which will lure in the public as opposed to being competitive to whatever the (unknown) solar + storage sticker price will turn out to be. (e.g. highly variable because it depends by "how frequent blackouts will your accept?")
Much of this regulation and process overhead is now being rolled back in the US (by both political parties) and Europe is slowly coming around to allowing new nuclear. NuScale is one of many next gen companies (I hope they're all successful), but the traditional large reactors are also great and can be built cost effectively.
The cost escalations and bungling were well in progress before the TMI. The NRC streamlined the reactor approval processes in the 1980s by trying to separate the licensing of a standard reactor from the licensing of the site -- nobody took them up on the offer.
In the case of AP1000 builds both Sumner and Vogtle were held up for years because they were waiting for Chinese factories to figure out how to make parts, in some cases they never figured it out and they had to source them elsewhere. Factory modular construction was supposed to prevent bungling at the site but replaced it with bungling at the factory.
In theory the factories got up the learning curve and if somebody ordered another AP1000 it would be different, in practice the AP1000 is a Chinese reactor and the Chinese gave up on it for the Hualong One which there are (oddly enough) two designs for, which goes back to the designs the French were using back when they were building many plants on time and on budget... which is maybe a good thing, but they look pretty quick to move on to the Hualong Two and before they get up the learning curve on that one they'll be switching to the Three...
I'll agree that the Europe hired somebody who thinks like Amory Lovins to design the EPR and really did bungle the politics more than the engineering, but that's not the story in the US.
Bar graphs showing decreasing regulatory cost on page 6. Pretty dramatic recent change.
https://www.nei.org/CorporateSite/media/filefolder/resources...
However they can't even put up wind turbines anymore, due to NIMBY issues, environmental concerns and whatnot. We had a ton of such projects but it's just about ground to a halt now.
And since our distribution network sucks, we've had a ~100x price difference between north and south for a long time now due to that, you can't just put it in the middle of nowhere.
As such I have very little faith they'll manage to put up a nuclear reactor in the near future, at least not close to initial cost and time. And none of that has to do with the details of building a nuclear reactor.
That said, there's change on the horizon. At least more and more people seem to be realizing that if they don't want wind turbines, they don't want huge swathes of solar panels and they don't want to alter more rivers then there's not a lot of options left on the table.
The right thing to do with something like the Vogtle plant for example would be to keep building them since you've just paid some very expensive costs learning what causes delays, but the knowledge of what gets the plant built - because it was built - is still there and fresh.
https://spectrum.ieee.org/amp/the-forgotten-history-of-small...
The problem is also: who pays for the hundreds of prototypes before the ”process” has worked?
But the people building power generation are doing it on a for-profit basis. Since solar is cheaper to deploy, faster to deploy, simpler to maintain and so on, that's what for-profit people build.
In other words, on the one hand you have large generators, requiring years of planning & permitting, a decade of construction, endless court battles from the anti-nuclear folks, generating returns 15 years from now, competing with the exact opposite (cheap, quick to build, beloved by eco folks, easy to run and maintain, off the shelf parts etc).
From a capital point of view its a no brainer. Capital follows profit, and solar is very profitable.
Nuclear may be good policy. Base Load may be very desirable. But unless govt is putting up the capital it just won't get funded. (Nuclear plants are being built, like in China, but using govt capital, which sees a return in more than just cash terms.)
There are lots of strong arguments for Nuclear. But Nuclear proponents need to address the capital requirements above all. Until the capital problem is solved, every other argument is useless.
If that's really the case then a Gen 4 reactor that runs at higher temperature, uses printed circuit or other advanced heat exchangers and a Brayton cycle gas turbine could win on the capital cost but it's easier said than done. There's not a lot of hope I think the LWR but the BWRX300 is at least trying to do it by deleting the heat exchanger and the only way you're going to get costs down radically will be by deleting things. Commercial Gen 4 reactors are at least 20 years out and we should have gotten started 20 years ago.
The natural gas plants without steam turbines are precisely the load-following plants that run for a fraction of the time (or at a fraction of their capacity); the relative weight of capital vs. fuel costs is inverted. (Or those, like xAI in Memphis, which are rapidly assembled in rushed desperation. I wonder if that will be a trend in the datacenter boom: designs limited, not by costs under normal market conditions, but bottlenecks affecting rushed projects. Nuclear SMR's would seem to be worst at this—the designs they expect to use haven't even been built yet!)
It isn’t just the turbine but the heat exchangers, in a PWR the ‘steam generators’ are water-water heat exchangers that are usually larger in volume than the reactor vessel. Many LMFBRs had two stages of heat exchangers (sodium-sodium and sodium-water) even larger heat on the water though SuperPhenix has relatively affordable secondary heat exchangers and never had them catch on fire.
Storage is making great strides but for it to get good enough to fully convert the grid we need qualitative advances in the underlying technology, not just manufacturing scale driving down prices.
In a world where both solar and wind are massively cheaper, that entire paradigm collapsed. Even more so when you can reuse the same hydro and gas that was working as peaking as "firming" to complement the new model.
We do have a HALEU advanced nuclear fuel supply chain issue. Thats being currently tackled. To your advanced reactor point -- they are also still far away so it is plausible that the supply chain catches up before any of the new reactors get deployed - assuming they make it to the finish line.
I should hope they make it to the finish line - I think we could do well with more nuclear providing our backbone of energy.
That really isn't the bottleneck by any means. If there's demand there will be supply.
> easily
That's and understatement. The PUREX process is a nightmare to get right, is expensive in both CAPEX and the specialized personell you need to pay, it produces much more deadly waste products, and you really don't want to proliferate it.
In the end, virgin uranium directly from ore is orders of magnitude cheaper for the foreseeable future.
'Going Nuclear - How the Atom will save the world' by Tom Gregory https://open.spotify.com/show/7l8wXWfPb3ZAUmd1pfUdv3?si=52fe...
Earlier this summer it was quantum computing, more recently optical computing, seems like the next one is going to be fusion!!
Polaris is supposed to pass theoretical breakeven, and maybe even technical breakeven - more electrical power out than they put in. That would be a huge event.
There seems to be a fair bit of progress notes from them. They aren't obligated to tell us anything, of course.
I like the idea of small reactors from a technical point of view. But I'm also a realist. To match current renewables growth (or even put a minor dent in it), many tens of thousands of these things are needed. They don't put out a lot of energy. In wind number of turbines it's something like 2-5 turbines per reactor. There already are tens of thousands of wind turbines. Plonking down a few hundred wind turbines is routine business. Getting the first small reactor online is still in progress.
In other words, small reactors are not happening anytime soon. Certainly not in the next decade. If there are a few hundred active small reactors in 15 years that would be really amazing. And if that happens at a reasonable cost (big if) relative to wind, solar, and batteries, that would be even better. But we'll be well into the second half of this century before these things are putting a dent into other sources of energy. And that's only if it all works out in terms of cost and technology. 25 years is not that long in nuclear. Long planning cycles are common. These things have a lot to prove.
I'm skeptical on especially the cost aspect. Nuclear proponents tend to gloss over the fact that nuclear has always been expensive. Things like waste handling and security add extra cost and small reactors just complicate that further. Small reactors have a lot to prove and the rosy projections tend to dodge the harder issues here. There's a lot of magical thinking around this topic.
In any case, a few hundred of these things would be a meaninglessly small drop in the ocean in terms of energy output. It's not coming even close to the yearly growth with solar, wind, and batteries. And MS needs data centers sooner than even those would be coming online. And the energy to power them. Wherever that's going to come from, it's (mostly) not going to be nuclear any time soon. Unless they drastically scale down their AI expansion plans. And long term this is a cost game. MS is going to need lots of cheap energy. Expensive energy just raises its cost. Unless small reactors fix the cost issue, MS won't be using a lot of small reactors.
For SMRs, all their work is still ahead of them. To get the learning rate going, you need to start mass production. Then you need to double that production again, and again, and again. Then, after 2-3 decades of doublings, you may be able to deliver $/Wh in the ballpark of where solar & storage is today.
Never mind that solar & storage will undergo multiple more doublings between now and then, and never mind that private industry will struggle to fund the required doublings for SMRs because it's not the maximally profitable choice on the margin.
It's just a very difficult pragmatic picture for nuclear.
I highly doubt that will be the case. Even if solar and wind do not get better costwise (which is likely not true) the cost of maintaining and decommissioning SMRs is likely only to go up. This based on every other nuclear power plant to date, I have seen zero good arguments on why SMRs would be an exception to that rule.
SMRs are more akin to mass manufactured widgets, where the scale benefits come solely from manufacturing efficiencies gained through volume. They'll have a learning rate that governs the price declines for each doubling in production volumes.
From a unit economics POV, it's probably more useful to think of SMRs as a solar/battery-like technology rather than a 1960s nuclear-like technology. The problem for SMR proponents is that solar/batteries have had 50 years of this feedback loop playing out, but SMRs are starting from no volume.
Agree that this solves many of the same problems as storage (as does overbuilding).
The PR problem with renewables is that the solutions are invariably cognitively complicated and multifactorial. The solution is going to be some kind of optimized result that mixes various storage forms, HVDC interconnects, overbuilding, and diversifying with solar and wind, and the exact nature of the solution is going to vary by geography.
It's just a hopelessly difficult communication challenge. If so many HN people can't grasp these concepts and jump to provably incorrect catchphrases like "storage is too expensive", then what hope is there for the general public.
Then there is the 'cool' factor ascribed to some solutions, an element of hope that a favorite technology will one day power the planet and all kinds of unrealistic assumptions about what is and what isn't technically, socially and economically possible. You are right that this is a difficult communications challenge but the level at which the discourse takes place is well below the minimum standards for taking part in such a debate.
We're talking about very simple basic and factual knowledge here we are still very far away from the complexity of say the 15 minute ahead market, balancing and long term cost projections of a particular technology, we are more in outright disinformation and denialism territory.
There is economies of scale for creating the thing, and then the economies of scale for the thing making electricity.
You can make nuclear reactors smaller under the assumption that you’ll be able to make them faster and cheaper over time. But the cost of the electricity they make goes up versus larger reactors because the costs for parts aren’t linear. An SMR is a basically a tiny plant for making electrify.
A solar panel doesn’t have this issue. Making the panel 2x, 5x, 10x bigger does not change the unit economics of the electricity it produces.
SMRs fix all the issues of modern nuclear reactors. SMR's are not 'small' in the absolute sense, they're on the scale of traditional power plants, not existing nuclear reactors.
They have a ton of advantages:
- They are inherently safe, no need to worry about meltdowns.
- They produce power comparable to existing power plants. Nuclear plants have huge issues with producing tons of power in a centralized manner, meaning the energy infrastructure needs to be designed around them, and probably you need a centralized infrastrucure for power distribution, which might not jive well with local politics. They also need huge concentrated cooling capacity, which might have negative ecological effects, and present a huge risk should they need to be shut down. The recent issues in France with global warming, where the rivers water level got lower and the water warmer, cutting down on cooling margins dramatically leading to shutdowns comes to mind.
- In contrast SMRs can be slotted into current energy infrastructure. Modern reactor designs can be throttled to match grid needs.
- SMRs are standardized, smaller and don't need to be built on site and can be built relatively quicker and cheaper. This is huge. If a traditional plant costs $20B and takes 20 years to build, the interest on the loans could mean it's never going to be financially viable. If you cound do something that makes quarter the power, but costs $5B and 5 years to build, it's an entirely different value proposition.
China is already building these, and they are the main country of origin for solar panels and equipment. Renewables make a ton of sense, but can't solve every issue.
You're going to need more work than a bare assertion to demonstrate this, given that storage exists, and given that gas peaking exists, and given that interconnects exist.
Consider these:
That assertion is not something everyone agrees with. And baseload is hardly ever qualified with even a ballpark estimate in GW or GWH of capacity needed. So, it's a fairly hollow and meaningless term.
And the reality is that for every 100GW added to grids world wide, about 80% or more is renewable. Nuclear is only small portion of the remaining capacity. And SMRs are a rounding error on that. Most of the rest is gas based generation.
Besides, data centers are a great example of something that can easily scale up and down its energy consumption based on price signals, user demand, etc. So, it's actually ideal to pair with fluctuating supply and demand from renewables. Using e.g. spot instances makes it easy for data centers to scale down their demand if energy is scarce and expensive. Other things they could do is throttle CPUs/GPUs based on energy pricing or encourage people to time shift non critical jobs to when energy is plentiful.
SMRs won't have fixed anything until there are lots of them. Whether you believe this will happen or not, it won't be happening very soon. Realistically, SMRs will remain a niche solution for decades to come; even if they do work at reasonable cost levels.
China has a few under construction, but having reactors built is not proof of them being viable, e.g. remember the superphénix.
Which is why old paid off nuclear reactors are today are being forced off the grids when renewables bring sustained low prices.
There’s a hundred and one “yes, but” objections to make, but our energy transition needs to throw everything at the wall and see what sticks. I don’t think it’s a choice between nuclear and other renewables. We need them all.
Economies of scale wins in big compute projects too
Have you been to a failed state? Bulgaria was in a state of disrepair when it comes to its industry, as kids we wandered to abandoned factories and I'm %100 sure that I don't wish a nuclear reactor to end up in a place like that. As 12-14 y/o kids we were going in, tear apart stuff the get interesting objects out like bearings, flat plastics etc. that we can use for games or making machines and if small reactors were a thing back then I'm certain that many disasters would have happened. AFAIK in Russia there are many lost RTGs, somehow nothing really bad happened but there are many instances of people getting exposed to radiation when working with recycling.
Nuclear reactors are very cool, they all have its place but please don't make it available to an average bozo that lucked on crypto or some greedy maniac in a failed state.
I'm sure in America it must feel inconceivable that states fail and things end up in wrong hands but where I grew up you can find remains of a few ancient empires + 1 quite recent ones with machinery and electronics unaccounted for.
What makes you think that this can't happen? It can happen in so many ways, i.e. the owner is criminal and runs away or fucks up and loses everything and the court takes years to decide who gets what from the factories, the new owners put it on sale it takes another 10 years to sell because the repair costs incurred are massive and equipment is getting obsolete therefore you can't find a buyer. People get old, move on and all that decays for 50 years until the land becomes valuable enough for someone to buy it with all that obsolete garbage.
It happens all the time.
People did actually die because of abandoned RTGs, see e.g. https://en.wikipedia.org/wiki/Lia_radiological_accident
Playing with lead, you notice that it lives traces on your hands, it looks wrong so you try not to play with the lead anymore.
A lightbulb with a shiny liquid in it? Don't break it or break it in open air at safe distance. Even if you touch the liquid make sure you wipe it out clean as it looks unnatural.
You easily develop instincts to detect what's dangerous with machines and chemicals, with nuclear you can't do that.
Ans as for the active ones, I hope they are taking good care of them. Bhophal 2.0 is indeed possible.
Anybody that still feels like that right now in America is not paying attention.
And yet, for most things, we see the opposite trend. We build big factories, big ships, big warehouses and yes, big power plants. We tend to make things as big as physics lets us do, because of economies of scale. For power generation specifically, big things tend to be more efficient, thanks to the square-cube law. For example look at big ship engines, they use specialized piston engines with cylinders you can fit into, not dozens or truck engines, even though the truck engines would be a good example of modularity.
And speaking of the "mainframe era", in a sense, that era was more distributed/modular than today. Companies had their own mainframe, whereas nowadays, it is centralized in huge datacenters. The servers themselves are modular, because we can't make a datacenter on a chip, physics get in the way, but having big datacenters help make economies of scale on cooling, power generation, security, etc...
I am not against SMR, they are an option worth considering, but if I had to bet between SMR and conventional, large size nuclear reactors, I'd go conventional. Someone mentioned China as taking SMR seriously, and yes, they do, but they are also building lots of big nuclear power plants, and they are doing very well at it.
That is what we did 20 years ago when the renewable industry barely existed.
What has happened since is that the nuclear industry essentially collapsed given the outcome of Virgil C. Summer, Vogtle, Olkiluoto, Flamanville and Hinklkey Point C and can't build new plants while renewables and storage are delivering over 90% of new capacity in the US. Being the cheapest energy source in human history.
We've gone past the "throw stuff at the wall" phase, now we know what sticks and that is renewables and storage.
The trouble is that:
a) "baseload" is a misnomer, what is required is storage to cover periods when "the sun doesn't shine and the wind doesn't blow"
b) CSIRO (our government research organization) releases a regular report called "Gencost" [1]. It has shown regular decreases in solar and wind, with costs for other solutions (coal/gas/nuclear) growing during the same period
c) The problem for nuclear power in AU is doubled because there is no local infrastructure or engineering or industry for the nuclear fuel cycle
d) AU home solar is world leading, with now a government subsidy available for home battery storage to soak up the midday peak, one state (SA) regularly runs on 100% renewables
e) SMRs do NOT exist in a commercially deployable way. There are any number of research and demo-scale possible SMRs, but none that are immediately able to be deployed
f) SMRs are too SMALL to replace existing coal gen, especially compared to the capacity of solar and wind farms, with offshore wind only just being started in AU
[1] https://www.csiro.au/en/research/technology-space/energy/ele...
"Storage" can't do that for more than smoothing out daily peaks. The only longer-term storage that matters when you look at the numbers is pumped hydro, and that's built out. That's why "baseload" is in fact quite relevant; it's way better to supply those critical needs via a highly reliable source.
The problem is that the issue of intermittent energy generation is unsolved. It is currently not feasible to use batteries for base load needs, it would be insanely expensive. Some day perhaps, but not yet.
There was never a technically solid plan to solve this issue by the German Greens, just wishful thinking. They undertook this massive project without having the faintest clue about the underlying physics and financials, which is hard to believe but true. The overwhelming majority of green party members are from the humanities, not STEM.
So you either have a lot of pumped hydro, in which case great, or you don’t, which is the case nearly everywhere but the nordics and perhaps Switzerland.
Solar is much better than wind btw, wind is simply a costly mistake as it is a lot more intermittent than solar. The math doesn’t add up.
The CSIRO report says that nuclear is almost 2x more expensive than renewables even after factoring in all costs of storage and interconnects.
> Solar is much better than wind btw, wind is simply a costly mistake as it is a lot more intermittent than solar.
That depends on the location. Insolation and seasonality vary depending on distance from the equator, among other factors. Also, solar and wind are negatively correlated on both seasonal scales and intraday scales, so it often makes sense to mix the two if you're in Europe, rather than pick a simple winner.
Wind makes extremely good sense and has been making good sense for 30 years or more now depending on where on the globe you are looking. There is a ton of FUD about it but it is practical, affordable, available and relatively fast to deploy. Moreover there is readily financing available to take care of the capex.
There are 7 MW turbines deployed regularly
https://www.enercon.de/en/turbines/e-175-ep5
And there are 10 MW turbines and higher on the drawing board. Offshore and onshore options are available.
It is none of those things.
You are in the most literal sense tilting at windmills here.
Culture war, innit.
I myself am located on the west coast of Scotland and we get most of our energy from wind. Solar panels make much less sense here we tend to get much less light than most places in the world.
This is a huge success already.
Continuing to burn fossil fuel is simply not an option. Not if we want to comfortable keep living on this planet.
1. electrify those applications currently served by gas 2. import or manufacture carbon-neutral synthetic gas 3. buy a heck of a lot of offsets
Arguing that "the economy would be better of without pollution/emission limits" is a bit like arguing that dumping trash in the next river is cheaper than proper disposal: Sure, your industrialists are gonna save a few bucks right now, but someone will have to pick up the bill regardless-- with interest.
Why haven't shareholders of energy companies also made sacrifices to save the environment? How come only the consumers have to?
Do you understand why people are pissed off with the switch?
My point of view is that "we have to curb emissions now before consequences grow too dire" is not a "luxury belief": the actual luxury is/was consuming fuel and fossil products without ever paying for the externalities. It was a luxury we could not actually afford at any point, basically just got it on credit in the past, and all that credit is coming due within the century.
> Why haven't shareholders of energy companies also made sacrifices to save the environment? How come only the consumers have to?
Because overall most of the benefit did go to consumers. People basically got a gallon of gas for 30 cents in 1960 when it probably needed to be a dollar or more, but companies like Shell only ever saw a small fraction of that retail price, and there is absolutely no way you could claw back that difference (or anything close, really) from them.
> Do you understand why people are pissed off with the switch?
I do understand the feeling of getting things denied that you took for granted, but I have little sympathy for selfishness.
Then why do current generations have to pay for the profits that the previous generations have banked?
>but companies like Shell only ever saw a small fraction of that retail price, and there is absolutely no way you could claw back that difference
YES, nothing we can do about the corporate overlords who screwed us, let's instead claw it back from the current generation of people instead of from Shell shareholders, that's will go down well politically for sure and not cause extremist rise to power. How is this not a luxury belief?
>I do understand the feeling of getting things denied that you took for granted, but I have little sympathy for selfishness.
It's not selfishness to afford necessities for a decent life especially when more and more of your paycheck goes towards taxes and necessities.
Life isn't fair and time travel doesn't exist. We are stuck with the world we have now and have to deal with the realities, including suffering the consequences for things not your fault. It isn't fair that a son gets cancer because his mother smoked around him all his life, but he is still the one that has to go through chemo.
The cost of food, water, energy and other things are going up *because* of climate change. What kinda "luxury belief" is that?
Maybe greedy corporate profiteering is the real culprit here squeezing people and not people using the AC or driving to work?
The environment consists of natural resources. Those resources have value and are "owned" by the people. You can save money by not changing the oil in your car, right up until the engine seizes up. Preserving the value of valuable assets through proper care and maintenance isn't exactly a high concept abstract concept.
It's like pumped hydro with a very predictable rainstorm directly above it every day. You'd be able to get by with a much smaller reservoir.
If you only need power for short periods of time when renewables are unavailable, then "constant output" plants like coal or nuclear are the last thing you want to build-- they are simply not worth it for the the short periods of time when renewables are down.
You want simple, cheap powerplants instead that trade off higher fuel costs for low capex, and that is currently gas. You want cheap MW (max power) from those plants instead of cheap MWh (energy), basically.
If they get undercut by renewables most of the time, there is simply no way they can stay competitive.
Nuclear peaker plants are not ever gonna be a thing, because that makes no sense economically: High capex is the last thing you want for that usecase, and it implies that the economics for your plant have to stay decent for the next 30 years. Meanwhile batteries, solar and wind are still getting cheaper every year right now. This is the worst bet you could ever make as an investor.
> nuclear may be a very sensible choice since a single nuclear plant can replace a whole lot of natural gas peakers.
This argument does not help nuclear power if the equivalent number of gas plants is still cheaper than a single nuclear reactor (and built much faster).
Because they are over-regulated. Why? Because of nucleophobia, which is fueled by fossil fuel producers.
In Ontario, Canada they are the third-cheapest (after hydro, and nat/methane gas); see Table 2:
* https://oeb.ca/sites/default/files/rpp-price-report-20241018...
In previous years they have often been second-cheapest (after hydro): their 'ranking' depends on methane gas commodity prices.
It's actually working great. Gas peakers are expensive to run, but not nearly as expensive and time consuming to deploy as nuclear - you could deploy a solar installation with matching gas capacity and still spend less and have it years earlier than the least expensive, fastest deploying nuclear power plant.
On top of that storage has been undercutting gas lately in terms of cost - especially now that it scaled up.
That is all affecting the economics of nuclear.
This does not align with reality.
Take a look at France. They generally export quite large amounts of electricity. But whenever a cold spell hits that export flow is reversed to imports and they have to start up local fossil gas and coal based production.
What they have done is that they have outsourced the management of their grid to their neighbors and rely on 35 GW of fossil based electricity production both inside France and their neighbors grids. Because their nuclear power produces too much when no one wants the electricity and too little when it is actually needed.
Their neighbors are able to both absorb the cold spell which very likely hits them as well, their own grid as the French exports stops and they start exporting to France.
ACC Natural Gas + Solar/Wind + Batteries + actively priced load shedding market seems like a tremendous quartet.
Besides, you've got to keep in mind that we aren't going to be building for yearly-average kWh consumption. Companies will be building overcapacity to take advantage of high-demand/low-supply peak pricing.
I don't think it is unlikely that we'll end up with a situation where PV on an overcast day is enough for "baseload", with the practically-free electricity on sunny/windy days opening up new economic opportunities.
'“Energy Droughts” in Wind and Solar Can Last Nearly a Week, Research Shows':
* https://www.pnnl.gov/news-media/energy-droughts-wind-and-sol...
See also:
* https://en.wikipedia.org/wiki/Dunkelflaute
I think it would be location-dependent (low risk that (e.g.) the UK would be windless for long stretches of time, especially off the coast).
A) It happens often enough to be a problem emergency capacity can't handle.
B) Natural gas is not always an option (especially when Russia is the only readily available seller in the area and you DON'T want to be dependent on a potentially hostile neighbor).
C) Existing storage solutions require a massive investment in local solutions, or in the national grid if storage is centralized.
We need to re-think the entire idea about energy always being cheap and available, while somehow preventing those with more money from simply monopolizing supply by outbidding everyone else. You won't solve that with batteries. Many therefore try to maintain the current situation by doing this the old way.
See the system described in the OP link at this thread:
https://news.ycombinator.com/item?id=45012942
Long term literally dirt cheap thermal storage coupled with extreme cost optimized PV that would provide 600 C heat 365/24/7 for as little as $3/GJ, on par with combustion of inexpensive natural gas. Complementary with diurnal storage from batteries, this would be a complete solution to the renewable intermittency problem.
That rooftop solar is delivering the cheapest consumer electricity in history.
Amazingly, the hardware costs and labor costs for rooftop solar are the same as the USA and sensible regulations around permitting and training have dropped the cost by 2/3rds.
People who don't live in such regions are likely to underestimate solutions that work well in these places.
That event is illustrative of the fundamental problem here. Green energy proponents pretend it never happens and do not factor diesel emissions into the cost of hydro and other solutions.
Another common way they mislead is by pretending that emissions from gas peaking plants are not inherently associated with solar and wind generating, even though they would not exist without them.
It's a kind of sleight of hand or green washing that should be called out more frequently.
100% renewable does not exist. Not in '100% hydro' Tasmania or anywhere else.
I feel we're going to keep seeing "solar doesn't work" posts in decades to come, long past when many areas of the world will already be on 100% renewables. It turns out that incremental deployment is a superpower.
There's no longer any good reason for AU not to be at >100% solar at midday every single day.
> SMRs do NOT exist in a commercially deployable way
.. while this is more of a problem. I could jokingly say that SMRs are a conspiracy by Big Turbine to sell more turbines. Also don't forget the need for water cooling, which may be a critical problem in AU.
Because complexity is expensive and those two are by far the most complex ways of generating energy, one of which is even so complex it hasn't even achieved net plus anyway.
Even a giant like Microsoft doesn't have unlimited funds to burn.
I already tried msreactor /scannow but don’t want to reinstall reactor as last time I did it I lost my city (and support only told to use boron or move to another area).
Please help!
rhdhfjej•16h ago
DeepYogurt•16h ago
JumpCrisscross•16h ago
No? The tradeoff is entirely one between the value of labour versus the value of industry. If dev hours are cheap and CPUs expensive. If it’s the other way, which it is in AI, you buy more CPUs and GPUs.
estimator7292•16h ago
Things like massively increased energy cost, strain on the grid, depriving local citizens of resources for your datacenter, and let's not forget ewaste, pollution from higher energy use, pollution caused by manufacturing more and more chips, pollution and cost of shipping more and more chips across the planet.
Yeah, it's so cheap as to be nearly free.
JumpCrisscross•15h ago
Both chips and developer time are expensive. Massively so, both in direct cost and secondary and tertiary elements. (If you think hiring more developers to optimise code has no knock-on effects, I have a bridge to sell you.)
There isn't an iron law about developer time being less valuable than chips. When chip progress stagnates, we tend towards optimising. When the developer pipeline is constrained, e.g. when a new frontier opens, we tend towards favouring exploration over optimisation.
If a CS programme is teaching someone to always try to optimise an algorithm versus consider whether hardware might be the limitation, it's not a very good one. In this case, when it comes to AI, there is massive investment going into trying to find more efficient training and inference algorithms. Research which, ironically enough, generally requires access to energy.
yannyu•15h ago
This is a peculiarly USA-localized problem. For a large number of reasons, datacenters are going up all over the world now, and proportionally more of them are outside the US than has been the case historically. And a lot of these places have easier access to cheaper, cleaner power with modernized grids capable of handling it.
> pollution from higher energy use
Somewhat coincidentally as well, energy costs in China and the EU are projected to go down significantly over the the next 10 years due to solar and renewables, where it's not so clear that's going to happen in the US.
As for the rest of the arguments around chip manufacturing and shipping and everything else, well, what do you expect? That we would just stop making chips? We only stopped using horses for transportation when we invented cars. I don't yet see what's going to replace our need for computing.
zekrioca•7h ago
And in the end, the cherry: “yes, the world is ending, so what can we do? I guess nothing, let’s just continue burning it so it dies faster.”
utyop22•13h ago
Ermmm. what?
infecto•16h ago
Edit: Amazing how anti-innovation and science folks are on HN.
logicchains•16h ago
irjustin•16h ago
juliangamble•15h ago
irjustin•13h ago
rhdhfjej•16h ago
adrian_b•15h ago
The idle power consumption of a human is around 100 W.
logicchains•1h ago
You should do some basic maths; the megawatts are used for serving many LLM instances at once. The correct comparison is the cost of just a single LLM instance.
wmf•9h ago
zekrioca•7h ago
bobthepanda•7h ago
You see this in other sectors where demand outstrips improvements in economy. Individual planes use substantially less fuel than they did 50 years ago, because there are now fewer engines on planes and the remaining engines are also more efficient; but the growth in air travel has substantially outpaced that.