After reading S. Levy's retrospective book on GE NE and ALWRs, SMRs were delayed for decades but came too little, too late.
There's essentially no general purpose point for them given the costs of PV and onshore wind have become cheaper to deploy. This is good for everyone so long as politic including techno-"religious" preferences doesn't subsidize coal, oil, gas, or even nuclear when there are cleaner and cheaper solutions today.
It's worth keeping in mind that 'low cost' PV comes from China (which makes 80% of the global supply of PV cells) which is run predominantly on coal (60% of their electrical energy) and China continues to build a GW coal plant approximately weekly, and incidentally, a new GW nuclear plant about monthly.
The coal plants China are building are peaker plants run at a fairly low duty cycle, most of their new power comes from solar. IOW they're building solar+coal instead of solar+batteries.
Number of coal plants is irrelevant. It's a misinformation.
What matters is how much coal they do burn. Their coal plants have capacity factor under 50%. Chinese consumption of coal is roughly as ~10 years ago (82EJ vs 88EJ). That is what matters.
Coal plants are going to balance the grid, just like in Germany.
nuclear has an opposite but related storage problem to solar and pv; whereas it's hard to reliably predict and line up solar and wind power, it is also generally hard to spin nuclear up and down quickly according to peak power demand as well. one of the first uses of pumped hydro was to store excess power at nuclear stations. https://en.wikipedia.org/wiki/Ludington_Pumped_Storage_Power...
transmission is also an issue at nuclear stations, because no one wants to live near one, and they generate so much power you would probably need additional transmission capacity wherever one was sited anyways.
Nuclear still loses to PV/wind even with those considerations. And it loses massively if you project those (especially PV) down their historical experience curves.
Seriously; do you really think the experts pushing PV/wind have not thought of this? It's been very well addressed.
I've seen that analysis - depending on how you model it, solar+wind+batteries is often still cheaper, plus batteries are solar are getting cheaper every year, while nuclear isn't (historically it's been getting slightly more expensive over time). So if it takes a decade to get a nuclear plant approved, even if it's competitive today, it probably won't be in 2034
Can a nuclear reactor be small enough that it doesn't need an expensive fence with 24/7 guards, and an expensive evaluation of the site for disaster risk?
I sort of suspect the answer to be no, but would like to hear arguments for yes.
This is in fact purely a political decision: a nuclear power plant is in reality less prone to being attacked than a virology lab, and the consequences are way less severe [1], then why should we expect the former to have much more stringent security rules?
[1] unless you leave the nuclear reactor unattended in the hands of terrorists for days, they won't be able to extract any nuclear material (which would be the worse case scenario and only one comparable to terrorist stealing a vial of Ebola or Smallpox)
How much (little?) radioactive material would there have to be inside the SMR for an impact of a 737 into the neighborhood to be more devastating than the release of the radioactive material?
Well, this doesn't answer your question, but there is also the issue of waste storage. In light water reactors, that's stored on-site for a long time. This research appears to indicate that with SMRs, this is actually a bigger issue.
> Small modular reactors (SMRs), proposed as the future of nuclear energy, have purported cost and safety advantages over existing gigawatt-scale light water reactors (LWRs). However, few studies have assessed the implications of SMRs for the back end of the nuclear fuel cycle. The low-, intermediate-, and high-level waste stream characterization presented here reveals that SMRs will produce more voluminous and chemically/physically reactive waste than LWRs, which will impact options for the management and disposal of this waste. Although the analysis focuses on only three of dozens of proposed SMR designs, the intrinsically higher neutron leakage associated with SMRs suggests that most designs are inferior to LWRs with respect to the generation, management, and final disposal of key radionuclides in nuclear waste.
Off the top of my head, if I had to protect a shipping container sized object from a 737, I would bury it. Dig a hole maybe the size of a residential swimming pool, build some drainage and some concrete walls with enough space to allow the container to get back out, stick the container in, and backfill outside the walls. Put a lid on it and cover it with local soil. As a bonus: anyone trying to steal it would need an excavator of some sort.
Or build an underground parking lot, park the SMR in it, put a serious door in front, and use the space above it for something else.
Conventional construction underground, especially of something complex, is expensive. But much of the point of an SMR is that it’s built off site and then installed. Driving a container down a ramp or lowering one off a crane is straightforward.
You should be able to make a reactor with anything larger than a couple kg of material.
Maybe you can avoid a thorium reactor if that size from being a valuable target. I have little idea about the social risks of somebody using the material as poison, instead of explosive, but I suspect it's incredibly overblown currently. (Wannabe thieves are probably way more effective going after something else.)
But well, don't expect very small reactors to be efficient or cheap. They maybe could be cheap heat sources, but electricity generation and distribution are full of scale efficiencies.
The lower limit is a nuclear lightbulb with ~20kg of uranium fuel, but that’s a high pressure reactor chamber that would definitely need to be protected and it needs large centrifuges inline to separate the fuel back out from the gas.
You may be vastly underestimating the amount of toxic waste produced by our energy production processes, renewable or not. (Wind, as I understand it, being the least nasty.)
> Ideally, the reactor would not need service until end-of-life (e.g. ~10 years). That way, it can be encased in concrete and buried.
This will blow up the level of radioactive waste that needs to be buried by about 1000x. Instead of a couple of kilos of long-lived isotopes after reprocessing, you'll need to bury THE WHOLE FREAKING REACTOR CORE.
> blow up the level of radioactive waste that needs to be buried by about 1000x. Instead of a couple of kilos of long-lived isotopes after reprocessing, you'll need to bury THE WHOLE FREAKING REACTOR CORE
Why the scare caps? The first word in SMR is “small.”
We currently wash out the industrial waste from processing and manufacturing our energy inputs and infrastructure. Also, nothing stops reprocessing those cores in the future. Next to a spent-fuel tank or tailings pool, a buried core seems preferable.
No, it won't be buried while it runs. The core can be buried, but it has to be in close proximity to steam generators and turbines.
And what "end of life"? Fuel will be exhausted in 3-5 years max. And I very much don't want disposable nuclear reactors. Modern PWRs are designed to last for 50 years and can probably last for 100.
TerraPower wanted to build "nuclear candle" reactors that can last for 50 years without refueling, but they had an inconvenient problem of requiring unobtanium for the reactor vessel walls (a material that can sustain 400-500 dpa, while the best steels can maybe push 150). "DPA" is "displacements per atom".
The argument about cost in this paper is complete bullshit anyway, since they are talking about one-shot reactors, of course it's going to be expensive, the main argument about SMR is that you're able to create multiple ones and improve the process to drive cost low as the learning curves kicks in (and without needing the kind of All-in France did in the 80s when they built 58 regular-sized reactor in 20 years, leading to very good economies of scale).
> The French, the article says, built 58 (ftfy) reactors, standardizing the parts and processes but still could not control costs
This is crazy bad faith at play here! Between the start of the French nuclear program and the end, two major international accident (TMI and Chornobyl) occurred and lead to massive changes in safety regulations. Of course it's going to have an impact on costs!
Also, in the meantime there had been a huge return on operation experience, which allowed to design plants that became cheaper and more efficient to operate (load following is much easier on the second generation than on the first for instance) but obvious lead to changes in design, but that's still part of the learning curve.
It's interesting to see a paper talking about how SMR are seemingly unfeasible in reasonable time when we already have plenty of small nuclear reactors being built somewhat in series: nuclear submarine and aircraft carrier engines.
It's hard to imagine commercial SMRs being built to the same standard as marine propulsion reactors, or receiving the same level of investment in ongoing maintenance.
Of course it's not going to be the same “standards” though, because the safety authority is much more rigorous when dealing with civil nuclear their your own soil than for nuclear submarines.
(and keep in mind that we're talking about French companies here, and France will need to replace 58 reactors in the next 30 years, so there will a huge need for mass production)
It should be noted that military naval reactors are still more expensive than propelling ships with liquid hydrocarbons. This is why most of the ships in the US Navy are not nuclear.
That's not actually what the paper says. It just says that when you have one design, when you find a design flaw, it affects all the instances. Due to the safety regulations, you then need to shut them all down until you've either fixed the problem or determined that's OK to restart. It's the risk of the monoculture.
And it then lists some examples from existing nuclear plants. So it's not a new problem.
(Background: I am an engineer that has spent most of their career in energy - fossil fuels, nuclear and renewables - the whole shebang. I care deeply about climate change, and recognise the non-negotiable need of humanity for ever-increasing amounts of energy.)
Take it from me - I would absolutely love renewables to displace all other forms of energy. However, from an engineering point of view, I know this is simply not feasible without some strong developments in energy storage and distribution. With today's technology, nuclear is the only real threat to the hegemony of fossil fuels, and the only practical hope of reaching climate goals (let alone long-term energy security goals). I think the fossil fuel industry knows this, and so frame their anti-nuclear rhetoric as a renewables-vs-nuclear debate, backing renewables.
If I wore a tinfoil hat, I would say that a lot of the support for renewables (and hostility towards nuclear) was encouraged/stoked/funded by the fossil fuel lobby.
There's an interesting blog that catalogues cases where the fossil fuel industry has scratched on nuclear. If you're interested, I'll link it below.
As for SMRs specifically, I think they have a lot of legs. Reactors that can be assembled (and serviced) in factories would go a long way to lowering the overall cost of the reactors (even accounting for the reduced energy-cost density of the individual reactors).
Questions welcome. I created an account just to give my two cents on a field to which I have dedicated my career.
- Too expensive.
Nuclear power plants usually operate for 40-80 years, making their ROI after the 20 year mark (greatly varies). The report's choice of "10-15 years" for a return on investment is suspicious, as it corresponds more to the life of PVs and wind turbines.
- Too slow.
The first instances of a new design always take longer than the mass production instances. It's madness to compare prospective factory-manufacturable reactors to the behemouth reactors we are used to today. (Also, from memory, I think Japan once made one of those behemoth reactors in 22 months... delays are often not for technical reasons).
- Too risky.
Without storage and/or distribution solutions, renewables will inevitably depend on fossil fuels; this applies both to service economies and manufacturing economies. The difference is that nuclear captures is externalities, unlike fossil fuels.
- A bad fit.
I actually agree with this one in some cases. For example, Australia has abundant land and great weather; they could probably get by with pure renewables. However, countries like Germany (which has so-so weather and some heavy industry) would be hard-pressed to do the same. They could achieve 100% renewables by giving up certain industries, but I don't think that's reasonable to ask.
- The Boeing Problem
Boeing's fall from grace has everything to do with perverse incentives and regulatory failure. If the public is crucifying them for dodgy planes, I imagine they'd do even worse for making dodgy reactors. Regulation is a must for nuclear, and never has anyone serious thought otherwise.
I love nuclear stuff, and I agree with you that SMR have a very good chance to become cheaper. I think we, the society, should invest in nuclear (specific nuclear fission) because of the immense energy density of uranium and thorium.
Yet, I think reaching our climate goals is entirely doable without nuclear.
Why? Net zero does not mean zero emissions. It means emissions equal to sinks. Right now in the US all the emissions coming from natural gas power plants are equal to all the sinks (generally forests) [1]. When I tell people that they are surprised. Here's the numbers: electricity contributes 25% to the emissions, and natgas power plants generate 45% of the emissions associated with power generation [2]. So 11.25% of emissions come from these power plants. The greenhouse gas sinks for the US are at 13%.
So, if we ditch all the coal power plants (which is happening right now, at high speed) and we build a lot of solar and wind, and keep all the current natural gas power plants as peakers, then we will be well below net zero.
> For example, Australia has abundant land and great weather; they could probably get by with pure renewables.
Maybe we (Australians) can do 100% renewable. We will see. But even if we never do (and it's not entirely clear how it's possible), it's hard to see a place for nuclear here.
Since you say you follow this closely, you are probably aware one Australia state is at 70% renewables. That's 70% average, over a year. Unlike other places you hear about with a lot of renewables, South Australia has no hydro. Like the rest of Australia SA is pretty flat, so it has no pumped storage either. In fact there is nothing special about SA at all, other than it has no coal or gas, and is at least 500km from anywhere else of note so transmission lines cost a small fortune. It's not an ideal place for renewables, but beggars can't be choosers.
I'd love to say SA hitting 70% was a master stroke of forward planning. It was anything but. You will hear some politicians claim the did it for climate change. Maybe it was, but what they did happened to coincide with taking cheapest option on the table at the time, over and over again. Solar and wind are damned cheap when they are only contributing 10%. Getting to 70% is more expensive, but they already had the natural gas peakers so at each step the options on the table were to import more natural gas, or put up a wind turbine and use less gas. Each % reduction gets asymptomatically more expensive of course. Over provisioning helps, but typically solar drives the price negative during the day now. They claim they will get to 100% in 2027, but without storage I don't have a clue how that's possible without using the transmissions lines to states with coal generators and some creating accounting.
It's possible the current 70% made the grid a unstable. It's hard to know. They did loose power for days, but the proximate causes were some transmission lines were blown over in the worst storm in decades, inter-state interconnects were down for maintenance, and wind turbines tripping out because of the spikes created by the first two. I'd love to say that had been anticipated and they were the victim of delays in building storage, but storage was deemed to be a money losing proposition. Hell, I'd even like to say the engineers stood up and said "we can fix this with a battery", but that didn't happen either. What actually happen is there was a political shit storm over whether the outage was caused by renewables, and the SA government found itself under an enormous amount of pressure to announce a fix. Elon, the masterful dick waving salesman that he is, proclaimed he could fix the issue by installing the world's biggest battery in 100 days - or it was free. It made headlines around the country, and they took him up on it despite the fact that it cost a small fortune and everyone knew it would lose money.
This is how the decision making process has always been. A complete cluster created by special interest groups fighting over their preferred way. It seems everyone hopes to win the fight by yelling at each other, including engineers like yourself. In the end the pollies throw their hands in despair and choosing the easiest option at the time. Everyone, and I do mean everyone including the engineers was wrong about that battery. It made money from the day it was installed. Turns out when a coal fired generator trips out and removes megawatts from the system in a single 50Hz cycle, to the computer controlling that battery that 20 milliseconds looks like an eternity. It can react in microseconds and dump compensating power into the system long enough for a peaker to fire up. And charge a small fortune for doing it. Apparently no one foresaw this, and so no serious grid scale batteries were added. Now everyone has seen they make money new battery installations are springing up like weeds all around the country. Again I'd love to say they are doing it for the climat...
Modern powerplants are closed-loop and do not consume water, although they may dump heat into it. Water is not consumed (in any great quantity) or contaminated, except that which is recirculated inside.
Power plants can be designed to work in hot deserts. The largest nuclear power plant in the US (Palo Verde in AZ) gets cooled by evaporating treated wastewater.
French nuclear power plants were just not designed for droughts.
They need heat sinks, not fresh + cold + clean water. Even the heat sinks are only really necessary due to concentration of generating capacity rather than the amount of generating capacity. For example, photovoltaic usually has thermodynamic efficiency around 20% while steam plants (nuclear, fossil, geothermal, etc) are usually around 33%: solar panels will release considerably more heat into the environment per unit of energy generated, but since it's spread out nobody cares. Small Modular Reactors are a big step in the "spreading it out until it's easy to get rid of" direction.
What does need (and not just "need" but actually "consume") fresh, cold, clean water (and dry air) is swamp cooling, which for some reason seems to do the rounds as as environmental silver bullet every few years. But that's a different rant.
From an outsider's perspective, SFR based designs look like hellish machines which are begging to burst up in flames. In contrast, I love the design of the properties LFR, except the material problems of high temperature lead. And in German circles the Dual Fluid reactor gets a lot of buzz as well.
I have a tremendous love for the fast breeder reactors (particularly Superphénix); that we had that technology so long ago astounds me. However, I recognise that they are technically challenging.
From a modern, pragmatic point of view, I'm very partial to SMRs and AMRs (advanced modular reactors). They are also easier to implement on non-technical grounds (e.g. site permissions).
Lead-fueled reactors are definitely an interesting area, and Russia is in the process of building a 300MWe demonstrator (BREST-300-OD). That being said, they have their own share of problems.
Startup and maintenance is going to be a beast, slowly heating up the reactor to working temperatures is going to take almost a year. The other problem is that it's still not clear if corrosion problems can be solved satisfactorily.
Reactor construction steel is stainless because it has a protective film of oxides on its surface, and lead gradually rubs it away (and then rubs away the construction steel, at a much faster pace). BREST-OD reactor designers spent a decade perfecting a system that is supposed to manage the amount of dissolved oxygen in lead, but it needs to be tested in the actual reactor conditions. With all its crazy temperature gradients and flows.
Another interesting area is light-water cooled breeders. Such reactors _are_ possible, but just marginally. And they have the nasty positive void coefficient, but it looks like it should be possible to compensate for it.
1. We need to be at net-zero by 2050 (and realistically based on the fast-moving temperature increases happening around us) maybe decades before that. SMRs haven’t been practically deployed yet, and don’t seem likely to be even minimally deployed until at least the 2030s if ever. How are we going to displace all forms of fossil fuel on the miniscule runway we’ll have left?
2. We have to deploy vast numbers of SMRs to the entire planet, including places with much worse security guarantees than first world nations. How do we propose to secure the huge amounts of fissile material and waste these reactors will use/produce. I’m not worried about fission bombs necessarily, but I am worried about pollution and dirty bombs.
3. “Without major improvements in storage” is doing a lot of heavy lifting. We’re seeing massive declines in storage prices and huge increases in production. If storage follows a curve similar to Solar PV, a huge fraction of the profitable applications for nuclear will be gone to cheap renewables and storage. Even if it doesn’t, renewables and today’s batteries are already driving fossil sources off the grid. How do we pay for a technology that will only have a few use-cases left after all the low hanging fruit has been eaten?
PS The last question is not a troll. It’s very obvious that renewables are going to generate something like 80-90% of our power. I’m open to the possibility that nuclear could make up the remaining 10-20%. But the economics of that chunk will be messy, since SMRs will have to compete with dirt cheap electricity when the sun/wind are available (even if storage stays expensive.) I highly doubt that SMRs are going to outcompete Solar PV when the sun is shining. What do the economics of the mostly-renewables-and-storage-with-SMRs-as-backstop world look like?
> I’m not worried about fission bombs necessarily, but I am worried about pollution and dirty bombs.
Realistically, the nuclear industry will just decide in a few years that it's too hard to properly dispose of waste and they'll dump it unsafely somewhere that it harms humans. This will be easier to do in countries that already have large hazardous waste problems. In the US it will require a great deal of lobbying, but at least 1/3 of the population will support it if they think it makes the economy stronger and sticks it to their enemies.
> We’re seeing massive declines in storage prices and huge increases in production.
Just in the last 9 months I’ve seen LFP prismatic cells from China drop 50% in price (and about 10% in pack volume). Add to that the variety of grid scale storage tech emerging out of R&D into the real world, by the time a nuclear reactor built today is coming online, it will be obsolete. More importantly, as renewables reach overcapacity, we need fast dispatch ‘peaker’ plants, not baseload, which makes gas a better transitional power source than nuclear, and batteries the end game
> I’ve seen LFP prismatic cells from China drop 50% in price
The comp would be the Nth-run cost of an SMR. It’s not something being produced anywhere close to utility scale to be topical over the next 20 years.
The world is bifurcating along renewables + gas (peaker), mostly the West, and renewables + coal (peaker-ish) and nukes (base), more Asia. Batteries may eventually replace some of that. But there are higher-value uses for them than grid storage for the foreseeable future (most obviously transport).
Globally, we are investing $1.5tn into new gas pipelines and terminals [1]. Anyone thinking those are transitional investments that will be written off in the next 20 years is deluding themselves.
> Anyone thinking those are transitional investments that will be written off in the next 20 years is deluding themselves.
I absolutely do not. Whether it’s nuclear or gas, transitional plants will either need to be subsidized or guaranteed by governments. As batteries come online, gas and nuclear will be dead.
> It’s not something being produced anywhere close to utility scale to be topical over the next 20 years.
I’m not sure that’s true, even for LFP. But flow batteries, pumped hydro, sodium ion are already there in terms of scale and economics, and don’t remove from storage where volumetric/gravimetric density matters, as with mobility.
Multitudes of other solutions like hydrogen production and more experimental energy storage are being actively researched, and I’d wager we’ll see more technologies in the mix in the next 1-2 decades that makes the nuclear discussion moot
> transitional plants will either need to be subsidized or guaranteed by governments
This isn’t some hypothetical, this is current investment being made under known terms.
Europe (nor America) can’t afford a trillion-dollar bail-out of its brand new gas terminals and pipelines. When demand starts being saturated, the existing infrastructure will take priority: every gas turbine, terminal and pipeline being built today will crowd out renewables down the line.
> As batteries come online, gas and nuclear will be dead
Possibly. Everyone seems to like a monoculture. The pro-nukes want only nukes. The pro-batteries want only renewables + batteries. Given that divide, it makes sense we’re betting on gas for the long term.
> I’d wager we’ll see more technologies in the mix in the next 1-2 decades that makes the nuclear discussion moot
> This isn’t some hypothetical, this is current investment being made under known terms.
Not sure what you mean here. Is it that private sector investments into gas? If so, it can't be said that it's a good investment. Plenty of bad investments happen, even in so called 'efficient' markets. At the end of the day, making a gas plant is a bet that we'll need more power than renewables can provide 1 - 2 decades from now.
> terminal and pipeline being built today will crowd out renewables down the line
If the energy can be had for cheaper, it will taken from renewables, though the losses may or may not be underwritten by the government.
If the argument is that renewable capacity will be insufficient 2 decades from now, well it would seem we'd need to vast increase in demand for that to be the case. That's not implausible, but certainly energy demand has been shrinking in western nations due to efficiency gains. Even AI, which seems set to increase energy usage, will be subject to efficiency gains as custom silicon, more efficient nodes, photonics, and other technological advances come into play
> Everyone seems to like a monoculture.
I'm not talking about a monoculture. As evidenced in this thread, I've talked about a mix of energy with gas in the equation. All I'm talking about is economics. Solar panels keep on giving (well past their previously expected lifetime of 15 years), wind farms keep on giving, with very little extraction or transport required, though transmission and, for now, backup, seem to be the pain points.
Personally I prefer nuclear from a conservation viewpoint – the waste and water usage problems not withstanding — as there's less land usage, and not a huge amount of extraction required.
> Barring antimatter weapons, no.
If we were to entertain this hypothetical, seems like there would be military budget enough to build whatever nuclear generators they need for their weapon (as they do for subs). I'm not sure on what timeline antimatter weapons enter the equation, but we could add the other hypotheticals of fusion or Dyson Spheres in the mix too
There is a certain price for renewables and storage where, yes, gas infrastructure will absolutely be dead. I don’t know what that price is: but it exists. And it won’t be the first time entire generations of capital investment have been torn up and thrown in the trash. Go out and take a look at what remains of the industrial Midwest.
But 20 years, where gas gradually becomes a backup seasonal fuel source and is increasingly displaced by renewables and storage? That is absolutely consistent with a net-zero-by-2050 world. And probably a shorter timeline than the one that gives us ubiquitous SMRs, unfortunately.
> is a certain price for renewables and storage where, yes, gas infrastructure will absolutely be dead
My point is the infrastructure is endogenous. Trillions in gas infrastructure investment creates real pushback against the price being allowed to get that low.
For Exhibit A as to how this will progress, see PG&E in California.
Wild to me how someone can open with something as ridiculous as recognising "the non-negotiable need of humanity for ever-increasing amounts of energy" and then be taken seriously. Its not only negotiable, its a requirement that we do not maintain such consumptive expansion.
Hey, I'd love to live like the elves in Lord of the Rings, but it's not gonna happen. The first world offloads its manufacturing burden to the third world, then criticises them for polluting the atmosphere with fossil fuels. Also, the majority of the world do not enjoy the standard of living we do in the first world, and they will want to. Like it or not, energy demand will increase. It is non-negotiable unless you think there'll be some great die-off.
The "strong developments" in the grid and storage you speak of is peanuts compared to trying to make nuclear cheap. Big, powerful companies with brilliant physicists and engineers have worked on it for decades. Lots of prototypes, lots of designs that didn't work out in practice.
Today, we don't actually need new tech for distribution and storage, although new tech is being developed and helps.
Chemical batteries for small-scale time-shifting and hydro plus gas plus biomass for larger scale. In 20 years, the youth of today will have to decide if they want to get rid of the last fossil gas - long term storage is on the order of 10% of total energy needed in the studies I've seen. It can be substituted with gas made from biomass. In fact, it's already happening in the country I'm in.
Distribution is just building more connections. I think working on improving the cost of underground connections would help, but it's doable with today's tech, and it is happening.
If anyone's interested, there are plenty of academic papers discussing this, and also a bunch of more accessible articles by this dude:
And yes, it's a complex topic. And yes, there will be some pain points along the way - energy is important to modern society, and it is a large transition that will years to unfold.
A personal take: the point for SMRs it's not costs nor potential mass-production and so on but a simple thing, they can be moved. We are in a changing world, we know, at least some of us know, we don't really know the future, but we know many will migrate and this means wars but also the inability to made fixed land infra, like roads, rails, electricity grid etc. Long story short: we need to have electricity "with us, moving" and p.v.+storage can works for a large slice of inhabited land but not enough, so we need something similarly easy to locally deploy.
I am sorry, but I think most of what you wrote is plain wrong. Yes, I agree, the total amount of energy used by humanity is going up. Especially as there are so many nations on earth which so far only use little energy. On the other side, it will somewhat go down from the current state for many leading industrial nations.
However, the bigger change will be how we use energy. In the last century the whole grid was optimized for a mostly constant load because that is what the then-used technologies, nuclear and coal, could do best. There were even big incentives given to customers to have a mostly constant draw of power. But now this changes. We have energy sources which produce electricity very cheaply, but not at a constant rate. And the experience shows, if the end customer is charged by availability, the consumption patterns change to optimize costs. This will be a big factor in the rollout of renewables.
As the article shows, cost-wise the SMRs can't compete. Renewables are getting ridiculously cheap. And even more: every one can set up renewables. You can go and buy yourself solar panels and put them onto your house or into your garden. The same advantage applies to industry-scale deployments. Same with wind. The only disadvantage with wind are the permits, as wind generators are quite big. But those are still trivial compared to nuclear, as the wind generators are not dangerous in any other sense.
Because they are cheap, the electricity markes are going to be flooded by renewables. That is basic economy. So the question is, how can we complement renewables best, especially to cover the gaps in their production. It won't be one thing, but a combination of several options as they are non-exclusive. Local conditions will put a stronger emphasis on one technology vs. the other. But one thing is clear: it won't be nuclear. Because even in the most optimistic szenarios, nuclear is a bad counterpart, as it is not good at providing varying output. Even if that is technically possible (usually it is not), economically it doesn't make any sense at all. For a transition time, it will be gas, as gas plants are relatively cheap and fast. Gas is expensive, so running the plants infrequently makes sense. The gas can later be provided out of renewable production. Most likely, battery storage will kill that too. But if not, the gas power plants can still be used.
And in all of that I haven't even touched the operational safety, nuclear waste, and of course giving nuclear technology to countries we don't trust.
SMRs never made any sense. They have all the same issue as "large" PWRs but they don't have the advantage of scale. Classic PWRs are big, but they produce a lot.
SMRs end up requiring exactly the same infrastructure as large-scale reactors, but they produce only a fraction of power. The largest PWRs will produce 1.6GW, but SMRs are designed for <100MW. So you need around 20 SMRs to replace _one_ large PWR.
When I look at the Ukraine situation I get very nervous thinking about having a large number of nuclear reactors spread out over a country. They would be perfect bombing targets and could contaminate wide areas.
Can you refer me to any project you are speaking about?
I consider it possible that they were planning new nuclear stations before the war, but since the war and the constant nuclear thread by the russians, I would be very surprised if there are larger projects planned.
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[ 3.4 ms ] story [ 133 ms ] threadThere's essentially no general purpose point for them given the costs of PV and onshore wind have become cheaper to deploy. This is good for everyone so long as politic including techno-"religious" preferences doesn't subsidize coal, oil, gas, or even nuclear when there are cleaner and cheaper solutions today.
What matters is how much coal they do burn. Their coal plants have capacity factor under 50%. Chinese consumption of coal is roughly as ~10 years ago (82EJ vs 88EJ). That is what matters.
Coal plants are going to balance the grid, just like in Germany.
What about the additional cost of storage/transmission to make those sources available 24/7?
Perhaps you've done that analysis and they're still cheaper, but I would automatically reject any argument that excludes storage/transmission.
transmission is also an issue at nuclear stations, because no one wants to live near one, and they generate so much power you would probably need additional transmission capacity wherever one was sited anyways.
Seriously; do you really think the experts pushing PV/wind have not thought of this? It's been very well addressed.
https://ieeexplore.ieee.org/document/9837910
Because they are still too big. They must be very small. Fuel efficiency is less important than creating economies of scale in manufacturing.
https://www.osti.gov/servlets/purl/840500 (page 6, table VII)
I sort of suspect the answer to be no, but would like to hear arguments for yes.
You means, like most industrial plants anyway or even college campuses?
An “expensive fence” and 24/7 security guard are still ridiculously cheap compared to the price of the thing itself.
Nuclear power stations are an extreme, not typical, example
[1] unless you leave the nuclear reactor unattended in the hands of terrorists for days, they won't be able to extract any nuclear material (which would be the worse case scenario and only one comparable to terrorist stealing a vial of Ebola or Smallpox)
> Small modular reactors (SMRs), proposed as the future of nuclear energy, have purported cost and safety advantages over existing gigawatt-scale light water reactors (LWRs). However, few studies have assessed the implications of SMRs for the back end of the nuclear fuel cycle. The low-, intermediate-, and high-level waste stream characterization presented here reveals that SMRs will produce more voluminous and chemically/physically reactive waste than LWRs, which will impact options for the management and disposal of this waste. Although the analysis focuses on only three of dozens of proposed SMR designs, the intrinsically higher neutron leakage associated with SMRs suggests that most designs are inferior to LWRs with respect to the generation, management, and final disposal of key radionuclides in nuclear waste.
https://www.pnas.org/doi/10.1073/pnas.2111833119
Or build an underground parking lot, park the SMR in it, put a serious door in front, and use the space above it for something else.
Conventional construction underground, especially of something complex, is expensive. But much of the point of an SMR is that it’s built off site and then installed. Driving a container down a ramp or lowering one off a crane is straightforward.
https://news.ycombinator.com/item?id=40540802
Maybe you can avoid a thorium reactor if that size from being a valuable target. I have little idea about the social risks of somebody using the material as poison, instead of explosive, but I suspect it's incredibly overblown currently. (Wannabe thieves are probably way more effective going after something else.)
But well, don't expect very small reactors to be efficient or cheap. They maybe could be cheap heat sources, but electricity generation and distribution are full of scale efficiencies.
A reactor that small needs highly enriched fissionable material. Of course it would need guards, since it's a proliferation nightmare.
You may be vastly underestimating the amount of toxic waste produced by our energy production processes, renewable or not. (Wind, as I understand it, being the least nasty.)
> Ideally, the reactor would not need service until end-of-life (e.g. ~10 years). That way, it can be encased in concrete and buried.
This will blow up the level of radioactive waste that needs to be buried by about 1000x. Instead of a couple of kilos of long-lived isotopes after reprocessing, you'll need to bury THE WHOLE FREAKING REACTOR CORE.
Why the scare caps? The first word in SMR is “small.”
We currently wash out the industrial waste from processing and manufacturing our energy inputs and infrastructure. Also, nothing stops reprocessing those cores in the future. Next to a spent-fuel tank or tailings pool, a buried core seems preferable.
It's "small" only when compared to full-scale PWRs.
And mines and tailing pools, to say nothing of acres and acres of panels and wind farms.
Sorry, but this idea is about as stupid as they come.
And what "end of life"? Fuel will be exhausted in 3-5 years max. And I very much don't want disposable nuclear reactors. Modern PWRs are designed to last for 50 years and can probably last for 100.
TerraPower wanted to build "nuclear candle" reactors that can last for 50 years without refueling, but they had an inconvenient problem of requiring unobtanium for the reactor vessel walls (a material that can sustain 400-500 dpa, while the best steels can maybe push 150). "DPA" is "displacements per atom".
I was thinking that too. But they addressed that in the article
Why will this time be different, when nowhere in the world has any nuclear industry succeeded in lowering costs over the life of a programme?
The French, the article says, built 55 reactors, standardising the parts and processes but still could not control costs
Russia (Rosatom) did it with the exported reactors. China is on track as well, although their finances are not as transparent.
This is crazy bad faith at play here! Between the start of the French nuclear program and the end, two major international accident (TMI and Chornobyl) occurred and lead to massive changes in safety regulations. Of course it's going to have an impact on costs!
Also, in the meantime there had been a huge return on operation experience, which allowed to design plants that became cheaper and more efficient to operate (load following is much easier on the second generation than on the first for instance) but obvious lead to changes in design, but that's still part of the learning curve.
https://i.pinimg.com/originals/1b/52/bc/1b52bcb5c6d5488cd256...
Of course it's not going to be the same “standards” though, because the safety authority is much more rigorous when dealing with civil nuclear their your own soil than for nuclear submarines.
(and keep in mind that we're talking about French companies here, and France will need to replace 58 reactors in the next 30 years, so there will a huge need for mass production)
We know how finantialisation of Boeing created its problems, that is well documented. If a SMR industry develops how can we mitigate those risks?
Boeing crashed two aeroplanes before it would even consider a problem existed. Then we saw the rot
Boeing were, we thought, the best of the best. How do we stop the same thing in a nuclear programme?
And it then lists some examples from existing nuclear plants. So it's not a new problem.
Take it from me - I would absolutely love renewables to displace all other forms of energy. However, from an engineering point of view, I know this is simply not feasible without some strong developments in energy storage and distribution. With today's technology, nuclear is the only real threat to the hegemony of fossil fuels, and the only practical hope of reaching climate goals (let alone long-term energy security goals). I think the fossil fuel industry knows this, and so frame their anti-nuclear rhetoric as a renewables-vs-nuclear debate, backing renewables.
If I wore a tinfoil hat, I would say that a lot of the support for renewables (and hostility towards nuclear) was encouraged/stoked/funded by the fossil fuel lobby.
There's an interesting blog that catalogues cases where the fossil fuel industry has scratched on nuclear. If you're interested, I'll link it below.
https://atomicinsights.com/smoking-gun/
As for SMRs specifically, I think they have a lot of legs. Reactors that can be assembled (and serviced) in factories would go a long way to lowering the overall cost of the reactors (even accounting for the reduced energy-cost density of the individual reactors).
Questions welcome. I created an account just to give my two cents on a field to which I have dedicated my career.
- Too expensive. Nuclear power plants usually operate for 40-80 years, making their ROI after the 20 year mark (greatly varies). The report's choice of "10-15 years" for a return on investment is suspicious, as it corresponds more to the life of PVs and wind turbines.
- Too slow. The first instances of a new design always take longer than the mass production instances. It's madness to compare prospective factory-manufacturable reactors to the behemouth reactors we are used to today. (Also, from memory, I think Japan once made one of those behemoth reactors in 22 months... delays are often not for technical reasons).
- Too risky. Without storage and/or distribution solutions, renewables will inevitably depend on fossil fuels; this applies both to service economies and manufacturing economies. The difference is that nuclear captures is externalities, unlike fossil fuels.
- A bad fit. I actually agree with this one in some cases. For example, Australia has abundant land and great weather; they could probably get by with pure renewables. However, countries like Germany (which has so-so weather and some heavy industry) would be hard-pressed to do the same. They could achieve 100% renewables by giving up certain industries, but I don't think that's reasonable to ask.
- The Boeing Problem Boeing's fall from grace has everything to do with perverse incentives and regulatory failure. If the public is crucifying them for dodgy planes, I imagine they'd do even worse for making dodgy reactors. Regulation is a must for nuclear, and never has anyone serious thought otherwise.
Yet, I think reaching our climate goals is entirely doable without nuclear.
Why? Net zero does not mean zero emissions. It means emissions equal to sinks. Right now in the US all the emissions coming from natural gas power plants are equal to all the sinks (generally forests) [1]. When I tell people that they are surprised. Here's the numbers: electricity contributes 25% to the emissions, and natgas power plants generate 45% of the emissions associated with power generation [2]. So 11.25% of emissions come from these power plants. The greenhouse gas sinks for the US are at 13%.
So, if we ditch all the coal power plants (which is happening right now, at high speed) and we build a lot of solar and wind, and keep all the current natural gas power plants as peakers, then we will be well below net zero.
[1] https://www.epa.gov/ghgemissions/inventory-us-greenhouse-gas...
[2] https://www.eia.gov/tools/faqs/faq.php?id=77&t=11
Maybe we (Australians) can do 100% renewable. We will see. But even if we never do (and it's not entirely clear how it's possible), it's hard to see a place for nuclear here.
Since you say you follow this closely, you are probably aware one Australia state is at 70% renewables. That's 70% average, over a year. Unlike other places you hear about with a lot of renewables, South Australia has no hydro. Like the rest of Australia SA is pretty flat, so it has no pumped storage either. In fact there is nothing special about SA at all, other than it has no coal or gas, and is at least 500km from anywhere else of note so transmission lines cost a small fortune. It's not an ideal place for renewables, but beggars can't be choosers.
I'd love to say SA hitting 70% was a master stroke of forward planning. It was anything but. You will hear some politicians claim the did it for climate change. Maybe it was, but what they did happened to coincide with taking cheapest option on the table at the time, over and over again. Solar and wind are damned cheap when they are only contributing 10%. Getting to 70% is more expensive, but they already had the natural gas peakers so at each step the options on the table were to import more natural gas, or put up a wind turbine and use less gas. Each % reduction gets asymptomatically more expensive of course. Over provisioning helps, but typically solar drives the price negative during the day now. They claim they will get to 100% in 2027, but without storage I don't have a clue how that's possible without using the transmissions lines to states with coal generators and some creating accounting.
It's possible the current 70% made the grid a unstable. It's hard to know. They did loose power for days, but the proximate causes were some transmission lines were blown over in the worst storm in decades, inter-state interconnects were down for maintenance, and wind turbines tripping out because of the spikes created by the first two. I'd love to say that had been anticipated and they were the victim of delays in building storage, but storage was deemed to be a money losing proposition. Hell, I'd even like to say the engineers stood up and said "we can fix this with a battery", but that didn't happen either. What actually happen is there was a political shit storm over whether the outage was caused by renewables, and the SA government found itself under an enormous amount of pressure to announce a fix. Elon, the masterful dick waving salesman that he is, proclaimed he could fix the issue by installing the world's biggest battery in 100 days - or it was free. It made headlines around the country, and they took him up on it despite the fact that it cost a small fortune and everyone knew it would lose money.
This is how the decision making process has always been. A complete cluster created by special interest groups fighting over their preferred way. It seems everyone hopes to win the fight by yelling at each other, including engineers like yourself. In the end the pollies throw their hands in despair and choosing the easiest option at the time. Everyone, and I do mean everyone including the engineers was wrong about that battery. It made money from the day it was installed. Turns out when a coal fired generator trips out and removes megawatts from the system in a single 50Hz cycle, to the computer controlling that battery that 20 milliseconds looks like an eternity. It can react in microseconds and dump compensating power into the system long enough for a peaker to fire up. And charge a small fortune for doing it. Apparently no one foresaw this, and so no serious grid scale batteries were added. Now everyone has seen they make money new battery installations are springing up like weeds all around the country. Again I'd love to say they are doing it for the climat...
Dumping heat into water is how they consume water. They either evaporate the water directly, or they heat a river, causing it to evaporate more later.
French nuclear power plants were just not designed for droughts.
What does need (and not just "need" but actually "consume") fresh, cold, clean water (and dry air) is swamp cooling, which for some reason seems to do the rounds as as environmental silver bullet every few years. But that's a different rant.
From an outsider's perspective, SFR based designs look like hellish machines which are begging to burst up in flames. In contrast, I love the design of the properties LFR, except the material problems of high temperature lead. And in German circles the Dual Fluid reactor gets a lot of buzz as well.
From a modern, pragmatic point of view, I'm very partial to SMRs and AMRs (advanced modular reactors). They are also easier to implement on non-technical grounds (e.g. site permissions).
Startup and maintenance is going to be a beast, slowly heating up the reactor to working temperatures is going to take almost a year. The other problem is that it's still not clear if corrosion problems can be solved satisfactorily.
Reactor construction steel is stainless because it has a protective film of oxides on its surface, and lead gradually rubs it away (and then rubs away the construction steel, at a much faster pace). BREST-OD reactor designers spent a decade perfecting a system that is supposed to manage the amount of dissolved oxygen in lead, but it needs to be tested in the actual reactor conditions. With all its crazy temperature gradients and flows.
Another interesting area is light-water cooled breeders. Such reactors _are_ possible, but just marginally. And they have the nasty positive void coefficient, but it looks like it should be possible to compensate for it.
1. We need to be at net-zero by 2050 (and realistically based on the fast-moving temperature increases happening around us) maybe decades before that. SMRs haven’t been practically deployed yet, and don’t seem likely to be even minimally deployed until at least the 2030s if ever. How are we going to displace all forms of fossil fuel on the miniscule runway we’ll have left?
2. We have to deploy vast numbers of SMRs to the entire planet, including places with much worse security guarantees than first world nations. How do we propose to secure the huge amounts of fissile material and waste these reactors will use/produce. I’m not worried about fission bombs necessarily, but I am worried about pollution and dirty bombs.
3. “Without major improvements in storage” is doing a lot of heavy lifting. We’re seeing massive declines in storage prices and huge increases in production. If storage follows a curve similar to Solar PV, a huge fraction of the profitable applications for nuclear will be gone to cheap renewables and storage. Even if it doesn’t, renewables and today’s batteries are already driving fossil sources off the grid. How do we pay for a technology that will only have a few use-cases left after all the low hanging fruit has been eaten?
PS The last question is not a troll. It’s very obvious that renewables are going to generate something like 80-90% of our power. I’m open to the possibility that nuclear could make up the remaining 10-20%. But the economics of that chunk will be messy, since SMRs will have to compete with dirt cheap electricity when the sun/wind are available (even if storage stays expensive.) I highly doubt that SMRs are going to outcompete Solar PV when the sun is shining. What do the economics of the mostly-renewables-and-storage-with-SMRs-as-backstop world look like?
Realistically, the nuclear industry will just decide in a few years that it's too hard to properly dispose of waste and they'll dump it unsafely somewhere that it harms humans. This will be easier to do in countries that already have large hazardous waste problems. In the US it will require a great deal of lobbying, but at least 1/3 of the population will support it if they think it makes the economy stronger and sticks it to their enemies.
Just in the last 9 months I’ve seen LFP prismatic cells from China drop 50% in price (and about 10% in pack volume). Add to that the variety of grid scale storage tech emerging out of R&D into the real world, by the time a nuclear reactor built today is coming online, it will be obsolete. More importantly, as renewables reach overcapacity, we need fast dispatch ‘peaker’ plants, not baseload, which makes gas a better transitional power source than nuclear, and batteries the end game
The comp would be the Nth-run cost of an SMR. It’s not something being produced anywhere close to utility scale to be topical over the next 20 years.
The world is bifurcating along renewables + gas (peaker), mostly the West, and renewables + coal (peaker-ish) and nukes (base), more Asia. Batteries may eventually replace some of that. But there are higher-value uses for them than grid storage for the foreseeable future (most obviously transport).
Globally, we are investing $1.5tn into new gas pipelines and terminals [1]. Anyone thinking those are transitional investments that will be written off in the next 20 years is deluding themselves.
[1] https://www.nytimes.com/2024/05/31/climate/greece-europe-nat...
I absolutely do not. Whether it’s nuclear or gas, transitional plants will either need to be subsidized or guaranteed by governments. As batteries come online, gas and nuclear will be dead.
> It’s not something being produced anywhere close to utility scale to be topical over the next 20 years.
I’m not sure that’s true, even for LFP. But flow batteries, pumped hydro, sodium ion are already there in terms of scale and economics, and don’t remove from storage where volumetric/gravimetric density matters, as with mobility.
Multitudes of other solutions like hydrogen production and more experimental energy storage are being actively researched, and I’d wager we’ll see more technologies in the mix in the next 1-2 decades that makes the nuclear discussion moot
This isn’t some hypothetical, this is current investment being made under known terms.
Europe (nor America) can’t afford a trillion-dollar bail-out of its brand new gas terminals and pipelines. When demand starts being saturated, the existing infrastructure will take priority: every gas turbine, terminal and pipeline being built today will crowd out renewables down the line.
> As batteries come online, gas and nuclear will be dead
Possibly. Everyone seems to like a monoculture. The pro-nukes want only nukes. The pro-batteries want only renewables + batteries. Given that divide, it makes sense we’re betting on gas for the long term.
> I’d wager we’ll see more technologies in the mix in the next 1-2 decades that makes the nuclear discussion moot
Barring antimatter weapons, no.
Not sure what you mean here. Is it that private sector investments into gas? If so, it can't be said that it's a good investment. Plenty of bad investments happen, even in so called 'efficient' markets. At the end of the day, making a gas plant is a bet that we'll need more power than renewables can provide 1 - 2 decades from now.
> terminal and pipeline being built today will crowd out renewables down the line
If the energy can be had for cheaper, it will taken from renewables, though the losses may or may not be underwritten by the government.
If the argument is that renewable capacity will be insufficient 2 decades from now, well it would seem we'd need to vast increase in demand for that to be the case. That's not implausible, but certainly energy demand has been shrinking in western nations due to efficiency gains. Even AI, which seems set to increase energy usage, will be subject to efficiency gains as custom silicon, more efficient nodes, photonics, and other technological advances come into play
> Everyone seems to like a monoculture.
I'm not talking about a monoculture. As evidenced in this thread, I've talked about a mix of energy with gas in the equation. All I'm talking about is economics. Solar panels keep on giving (well past their previously expected lifetime of 15 years), wind farms keep on giving, with very little extraction or transport required, though transmission and, for now, backup, seem to be the pain points.
Personally I prefer nuclear from a conservation viewpoint – the waste and water usage problems not withstanding — as there's less land usage, and not a huge amount of extraction required.
> Barring antimatter weapons, no.
If we were to entertain this hypothetical, seems like there would be military budget enough to build whatever nuclear generators they need for their weapon (as they do for subs). I'm not sure on what timeline antimatter weapons enter the equation, but we could add the other hypotheticals of fusion or Dyson Spheres in the mix too
But 20 years, where gas gradually becomes a backup seasonal fuel source and is increasingly displaced by renewables and storage? That is absolutely consistent with a net-zero-by-2050 world. And probably a shorter timeline than the one that gives us ubiquitous SMRs, unfortunately.
My point is the infrastructure is endogenous. Trillions in gas infrastructure investment creates real pushback against the price being allowed to get that low.
For Exhibit A as to how this will progress, see PG&E in California.
The CAISO grid makes use of all 3, with solar and storage being used more and more, as shown here (I just picked todays date, but I think the trend applies to most days): * https://www.gridstatus.io/live/caiso?date=2020-05-30 * https://www.gridstatus.io/live/caiso?date=2024-05-30
In addition the UK grid has seen a large expansion in renewables underpinned by it's own nuclear fleet and imports of French nuclear power (https://www.mygridgb.co.uk/historicaldata/, https://grid.iamkate.com/).
Today, we don't actually need new tech for distribution and storage, although new tech is being developed and helps.
Chemical batteries for small-scale time-shifting and hydro plus gas plus biomass for larger scale. In 20 years, the youth of today will have to decide if they want to get rid of the last fossil gas - long term storage is on the order of 10% of total energy needed in the studies I've seen. It can be substituted with gas made from biomass. In fact, it's already happening in the country I'm in.
Distribution is just building more connections. I think working on improving the cost of underground connections would help, but it's doable with today's tech, and it is happening.
If anyone's interested, there are plenty of academic papers discussing this, and also a bunch of more accessible articles by this dude:
https://cleantechnica.com/author/mikebarnard/
For instance, here's a recent one
https://cleantechnica.com/2024/04/11/the-short-list-of-clima...
And yes, it's a complex topic. And yes, there will be some pain points along the way - energy is important to modern society, and it is a large transition that will years to unfold.
What do you think about that?
However, the bigger change will be how we use energy. In the last century the whole grid was optimized for a mostly constant load because that is what the then-used technologies, nuclear and coal, could do best. There were even big incentives given to customers to have a mostly constant draw of power. But now this changes. We have energy sources which produce electricity very cheaply, but not at a constant rate. And the experience shows, if the end customer is charged by availability, the consumption patterns change to optimize costs. This will be a big factor in the rollout of renewables.
As the article shows, cost-wise the SMRs can't compete. Renewables are getting ridiculously cheap. And even more: every one can set up renewables. You can go and buy yourself solar panels and put them onto your house or into your garden. The same advantage applies to industry-scale deployments. Same with wind. The only disadvantage with wind are the permits, as wind generators are quite big. But those are still trivial compared to nuclear, as the wind generators are not dangerous in any other sense.
Because they are cheap, the electricity markes are going to be flooded by renewables. That is basic economy. So the question is, how can we complement renewables best, especially to cover the gaps in their production. It won't be one thing, but a combination of several options as they are non-exclusive. Local conditions will put a stronger emphasis on one technology vs. the other. But one thing is clear: it won't be nuclear. Because even in the most optimistic szenarios, nuclear is a bad counterpart, as it is not good at providing varying output. Even if that is technically possible (usually it is not), economically it doesn't make any sense at all. For a transition time, it will be gas, as gas plants are relatively cheap and fast. Gas is expensive, so running the plants infrequently makes sense. The gas can later be provided out of renewable production. Most likely, battery storage will kill that too. But if not, the gas power plants can still be used.
And in all of that I haven't even touched the operational safety, nuclear waste, and of course giving nuclear technology to countries we don't trust.
SMRs end up requiring exactly the same infrastructure as large-scale reactors, but they produce only a fraction of power. The largest PWRs will produce 1.6GW, but SMRs are designed for <100MW. So you need around 20 SMRs to replace _one_ large PWR.
The math just doesn't work out.
Economy of scale can lower the price a bit, but not by an order of magnitude.
Based on what? Orders of magnitude are the norm in manufacturing. We’re seeing it in batteries right now.
And don't forget, SMRs need to be at least 2 orders of magnitude cheaper for your hare-brained idea of "dispoasable reactors" to work.