Your volume is low,or you just don't talk loud.

From what I understand, they burn up the long life actinides, or waste. So instead of spent fuel being dangerous for millions of years, it is only for 100s of years.

The fact that they take half life actinides and reduces that from tens of thousands of years to 100s of years should be pursued regardless of cost as the economics will always support it. If you want to have your head really melted delve into the history behind molten salt reactors and how the world essentially got fucked over by politics in the US at the time. When you think about any MSR design and features compared to a light water reactor design its nothing short of sheer insanity that anything that dangerous was advocated for let alone propagated as the default technology for civilian nuclear power generation. With all the focus on a decarbonisation its maddening to think we are 60 years behind where we could be all because of political decisions and something to bear in mind as there is advocacy for what can only be described as delusional green wrapped policies.

Could you also make a video about Canada's advancement in Artificial Intelligence and Quantum Computing? It is very interesting to me how Canada (a sparsely populated country) is a global leader in those fields as well.

@@davidcullen4996 I find it insane Thorium reactors were not developed and produced. We certainly made mistakes

''''nuclear waste from power plants shouldn't be as big of an issue as it is.'''' Why should it be ? The natural halving works for us . If the planet earth has yearly 100.000 tons nuklear waste , those humanity will have after 700 millions years 50.000 tons nuklear waste . Again after 700 million years it's 25.000 tons and so on . But bad news is ; We will have every year 100.000 tons in addition and our maths can't count how big the accumulation is .

@@alimali2120 I think he means that, rather than being a big issue as it currently is, there are likely multiple solutions for dealing with the "waste" other than just containing it in storage facilities.The main problem is that energy production is profit driven, so after the profitable part of the system is complete they want the cheapest solution possible for dealing with the waste. In my opinion, reprocessing the material into less dangerous components should naturally be a base level requirement. Still not an ultimate solution, but at the slow rate we are progressing, there should be the highest level of damage control possible, until they settle on a more responsible system of energy production.

@@brt5273 Recycled waste would reach background radiation levels in roughly 300 years. By continuously recycling the waste there would be no build-up. Most people don't understand radioactive decay half-life. Waste with half-life in the millions of years is not a problem as we're already surrounded by rocks and minerals with similar radioactive decay. Long half-life means less radiation.

@@SirRebonack Agreed. It's the best solution until or if they finally discover a better source.

@@alimali2120 the thing is a kilogram of u235 is enough to power a city for a decade. the primary nuclear waste is very minimal. But the secondary and teritiary wastes are the bulk if the nuclear wastes which are not that radioactive like the plumbing and the gloves and apron used to handle the nuclear material.

Yes, for too long, the anti nuke crowd has used terminology like "waste" that only instills fear, not understanding. I think people are finally coming around though; even the founder of Green Peace is more friendly to nuclear than he was in the past.

There is no point in making a new reactor unless it's "walk away" safe. They need to be able to turn the key off on Friday and turn it back on Monday if need be. In the event of any cataclysmic disruption, the reaction ceases and the nuclear fuel is spread out enough to become harmless indefinitely. Seriously, we don't need another Chernobyl. Make it physically/mathematically impossible even if you try. This is the way.

Yes, but let's put things into perspective. Fukushima's accident killed 0 people (possibly 1 person but hard to prove). Most industrial accidents kill more people and barely ever make the local news. The evacuation killed thousands more. That's the scary part. Overreacting due to caution turns out to be more dangerous.

Gen 3+ are requirewd whitstoud Long term lost of power incidents, whitout problems... well after Fukushima States and plants invested on Hellicopter based response teams in (extremly unlikely) event happed which would put out of order standart on site metods to provide power for emergency cooling systems. so lessons was learned,...

@@marianmarkovic5881 Fukushima had been recommended to move their backup generators to the top of the containment buildings years before, and refused to do so.

@@nuanil first, having heavy diesel generator at bottom make a lot of sense if you thing about resistance against earthquake. But true, there was that kind of suggestions. But newer forget, a a lessons are learned, and although it was heavy accident, most areas hit by fallout are decontaminated to point it's safe to return.

@@blackandcold What's not answered? Molten Salt Reactors are the answer, and were well on their way to becoming a commercialized reality 20 years before Chernobyl happened.

Fast sodium cooled reactors aint nothing new,... from US EBR, and Soviet BN series,... Soviets also used molten lead-bismut conpound as cooland, in fast reactors... which mean idea well tested and proven,... but PWR were more cost-efficient so far.

The world needs more Canada

@@bradjames6748 actually Canada is kinda authoritarian. The nuc engineering is good.. but I'd not want to go there after the last year an a half has shown their true colors

Unfortunately it's not in abundance these days

The title is misleading. The reactor still produces radioactive Cs, Sr, etc which must be stored for 1000+ years.

It really infuriates me how a project like the Onkalo waste storage in Finland is being praised. We'll be able to literally turn waste into free energy for decades to come, and then a multi billion dollar project to bury that free energy forever is receiving praise???

I think salt can be used to put out fires on the stovetop too, so that could be right.

I'd rather trust liquid sodium than water. I well remember my 8th grade science class, 1959. Mr. Zweig took a small piece of pure sodium from its kerosene environment and let it burst into flames. Cool!

Japan was so backward they managed to melt down a LWR,we should never take cues from Japan,in fact the Bill Gates company is already building the Natrium system for a closed coal plant in Wyoming.

Japanese are quite backwards, they managed to melt down a Lee something no one else has managed now they insist on building coal plants because they have no faith in science.

Research in molten salt reactors is going on current with other research projects in Canada and the US.

Well said! 😁

Probably some political interference from an upset other client nation …

Politics... nuclear energy is full of it. Oil companies don't like them, and they have money to run disinformation campaigns. I even bet Greenpeace gets a lot of donations from oil companies.

It was a loop type reactor that was plagued with sodium leaks, theBritish government did not have the wherewithal to work though the problems, that combined with the discovery of large uranium deposits reduced the incentive to continue. Many loop type fast reactors suffered a similar fate.

It cost a fortune, the reprocessing of nuclear fuel was expensive and demand for it fell, In the eighties gas power stations were built. Building nuclear power stations seems to always overrun on time and cost. If the government doesn't underwrite them in some way they are uneconomic. E.g. the 7gw station under construction by EDF was guaranteed an electricity price of 90GBP/MWh when other sources could be built to generate at half the cost. This was justified as diversity of power sources and base load.

@@chrisdaniels3929 Again, politics. Nuclear power is expensive because of regulations. Because people are afraid of it.

So true!

Besides, it's not safe because of assembly wear during operation. And I cannot imagine how fuel from one reactor type would fit into another reactor type/design. It is different even between models of one reactor series.

@@wwlb4970 - The fuel would need to be removed from tubes and reprocessed to work in molten salt reactors. We have been reprocessing old nuclear weapon grade uranium into fuel for over a decade.

@@WJV9 Depending on what you call fuel. I call fuel assemblies fuel, as a minimal working unit currently in use. Besides, can you point out any working industrial molten salt reactor?

@@WJV9 Also, reprocessing highly enriched uranium into fuel is quite easy. Reprocessing fuel assemblies is quite a different, and a very long story.

Where has rickys comment gone? Interesting he should reply to me with a comment as such and can make such a judgment from one sentence. I work with wind turbines so know a bit about them… but I guess that makes me sub 80 Intelligence. His comment makes me think he’s a true commie

The federal government website has some info about SMRs in Canada. Lot's of talk but no one is willing to spend the billions needed. The BN-800 reactor is a first of it's kind. Program started in 2016 with the reactor going online in 2019.

@@DennisCambly BN-800 program actually started in 1983 and stopped due to Chernobyl accident in very different type of reactor, end of the USSR, etc... Project resumed in 2006 getting at full power in 2016. We are at a point where it doesn't matter what type of reactors are built, if it is done fast and cheap enough people will realize this is the only way forward. Modern reactors like APR1400 or AP1000 have a lot more passive safe we could hope for. China is working on MSR, this are even more advanced, although we might wait a decade or so before they make commercial power station with this technology.

@@codaalive5076 I understand what you are saying. We need to look at the fact any reactor will take years and a lot of money before it is ready. The media is hyping reactors of all sizes as a quick fix. They are not. Meanwhile the millions of tons of spent nuclear fuel needs to be dealt with worldwide.

@@codaalive5076 I understand what you are saying. We need to look at the fact any reactor will take years and a lot of money before it is ready. The media is hyping reactors of all sizes as a quick fix. They are not. Meanwhile the millions of tons of spent nuclear fuel needs to be dealt with worldwide.

@@DennisCambly Media is still into oil, at least mainstream. In 60's politicians with help of oil barons decided they don't want MSR capable of using fuel so much more efficiently nothing else comes close. Nuclear waste? You produce 1 can of Fanta of high level waste in your lifetime, if all power would be from nuclear this would amount to maybe 10 cans or much less with MSR and some other technologies. Don't worry about it because CO2 is so much more dangerous. Coal is killing 850.000 people every year, probably a lot more. Did you ever hear about civilian nuclear waste or even accidents killing thousands? No.

Getting away from a sodium cooled reactor is a good thing.

While the Russians have built lead-bizmuth cooled reactors, the BN series are sodium cooled. BN-600 in operation from 1980, BN-800 since 2014 and BN-1200 is still in development. There are outstanding problems with PbBi coolant including corrosion and production of Po from activation of Bi which complicates maintenance

We lost decades investing in nuclear power instaed of renewable energy.

Jane Fonda one women more responsible for millions of deaths worldwide. An enemy of the people.

thank you for your service to humanity

The real killer was Clinton/Gore when they cut the Integral Fast Reactor off in mid 90s, which is somewhat ironic in that it was one of the big solutions to Gore's hockey stick CO2 graph.

All true Florent and for new ultra high tech (like reactors, aircraft, etc...) another factor contributes massively as well and that is the huge sunk R&D costs get spread over many units, not just the tooling. Add to that designing things so as much as possible can be produced in a modular fashion in a factory instead of onsite and the potential is there to make things much cheaper than they would be otherwise.

@@richardbaird1452 they are building regular SMRs too and this technology can’t compete with price for them and is why this technology isn’t going anywhere. It’s more expensive. They don’t want to pay for it.

@@TheBooban Not sure what a "regular SMR" is, since none have been built yet. There are 3 first of a kind designs in Canada that are actually proposed for building and either in or getting ready for licensing discussions. The first is the MOLTEX SSR-W which is a molten salt waste burning fast spectrum design 300MWe class proposed by NB Power. Then there is the ARC-100 which is a sodium cooled metal fueled fast spectrum of ~100MWe also by NB Power. Lastly there is the Ontario Power Generation proposal for a BWRX-300 which is a thermal spectrum boiling water design in the 300MWe class. There are other programs in development as well (e.g. Terrestrial Energy and a bunch of others using CNSC pre-licensing to advance their designs), but those are the three which actually have utilities planning implementation. The first two can both participate in waste reduction using appropriate reprocessing tech. So I would say it is far too early for your "They don't want to pay for it" statement.

Ah Yes Russia the nation that gave us Chernobyl, Nyonoksa, Kyshtym, Tomsyk etc etc. Ya I would suggest anyone touting ANY Russian Nuke technology should probably think twice before commenting, Especially since the Russians have had more nuclear accidents and failures than the rest of the planet combined. The only that can be learned from the Russian nuke programs is how to NOT do something.

@@matthewq4b Bullshit

Russia is incredibly backward, very poor people struggling to stay alive, yes Russia does lead in fast reactors ,but that won't last, and their nuclear output is pitiful compared to US reactors.

What about all the spent fuel Russia dumps in the ocean?

@@matthewq4b Rave! Over the past 20 years, Russia has built more nuclear reactors than the rest of the world (mostly foreign orders).

Agreed, thorium fast breeder liquid salt are safe cheap and versatile

If there was an existing IMSR, and there is not.

@@Nill757 yeah, that bothers me too. Can you write some emails to OPG and get them to hurry up and make a decision for their Darlington SMR vendor?

@@Nill757 The EBR2 was an IMSR,the US ran it for years, we did not lose any of that information, the IMSR from Terrestrial is the result.

@@paulbedichek2679 EBR2 prototype was a solid fuel reactor, fast spectrum, sodium cooled. It was actually built and operated for a time. IMSR is none of those things. There is not yet any existing IMSR, not anywhere in the world, nor any license to build one in the US.

@@Nill757 Good point, IMSR has more in common with the aircraft reactor experiment, with molten salt molten fuel. We have had lots of experience with Graphite which is why they just replace the reactor after 7 years.

They use multiple coolant loops and heat exchangers. The primary coolant (that passes through the reactor) remains a liquid at operating temperature and therefore does not have to be at high pressure. The primary coolant then passes through a heat exchanger where heat is transferred to a secondary water loop to produce the steam needed to drive the turbine. This loop is at high pressure, but because it does not pass through the reactor it does not become radioactive (or contain radioactive by-products) and can be released to atmosphere if necessary. The pressure vessel of a traditional PWR reactors is designed to contain a release of steam from the primary (radioactive) coolant water.

Sodium in reactor condition is liquid in standart pressure,... unlike watter which need extremly high pressure to remain liquid. But well if there is leak, You still have problem,.. since Sodium is extremly high reactive and burns once in open air, and you cannot use water to gauge fire since it kick hydrogen from water, so fire continues and you have extra hydrogen flying around :). So in similar facilities there was not even bathrooms, and around facility was on hand buckeds whit sand, in case of (small) leak and firefighting was needet.

@@bobthebomb1596 I very much appreciate this explanation

@@marianmarkovic5881 Yeah, I am not a fan of sodium cooling. There look to be less troublesome ways to do it.

@@bobthebomb1596 Well if you keep water and oxygen away from it any meltdowns aren't a big deal to the public :P

This utilizes the uranium 238 by turning it into plutonium and then fissioning it. Will still have the daughter isotopes from plutonium fission.

@@stefanr8232 You can get surprisingly far down the fission chain in a fbr. I believe most of the fuel ends up as lead

@@appa609 Stefan is correct. The difference in a fast spectrum is that the vast majority of the fission products have relatively short half-lives and you can fission the actinides (the really long lived stuff) out of the stream. The waste doesn't actually turn to lead...but the radiotoxicity degrades to original ore levels within a few hundred years (vs. 10s-100s of thousands).

Though upcoming small modular designs are hoping to bring down costs through standardized production, until they arrive nuclear remains an expensive power source. Nuclear also makes for a fantastically reliable baseload, but struggles with throttling up and down. If you rely solely on nukes, you're either going to have far too much power at midnight, or not nearly enough at 7am. Diversity in generation alongside some form of power storage will be key for future grid stability through mismatched supply and demand peaks.

3:22

Use thorium.

@@oldman2800 Sodium is the coolant not the fuel.

Superphenix was a prototype it has been shut down only for political reasons and France has worked on it's successor with Astrid wich is currently stopped but a comeback is still possible since Macron changed is mind. The main issue for Astrid is the cost and France is looking into partners to finish the project.

Ooo What idea? care to elaborate?

Except that salt destroys metal.

most of the time when molten salt is mentioned, Sodium is the molten salt... Yes It's a problem but it's a problem that can be handled and has been handled numerous time in the past in the various experimental ( or not so experimental ) fast breeder reactors that used sodium as a molten salt.

@@tenalafel "salt" means sodium chloride but could mean lithium fluoride or several other combinations. LFTR reactors are a category. The "sodium coolant" means actual sodium element. Like the stuff in low-pressure sodium light bulbs. Sodium is liquid over a wide range of temperatures. The boiling point is very pressure sensitive so it is very easy to regulate temperature throughout a complex system. Downside of sodium or NaK is the tendency to burn, to react violently with water, and to react with (corrode) many types of material. As a coolant is marvelous. Neutron activated sodium has a 14-hour half-life and becomes stable calcium which separates easily. Safe to dump or recycle within a week. If you have a sodium cooling system that works safely in a non-nuclear setting then it will work safely cooling the reactor too. Swimming pool sized vats of liquid sodium are scary all by themselves.

@@0MoTheG Salt is only corrosive when combined with air or water. They take steps to ensure that these are not present.

@@0MoTheG Contaminated salt could attack alloys. The salt can be continuously processed.

Jospin is a criminal.

@@AlldaylongRock why?

@@pierrekilgoretrout3143 he closed SPX prematurely. When most bugs were fixed. He made SPX look like a failure and a money pit, instead of using the technology to further improve the French Nuclear power program.

Right, molten salt reactors with lots of fuel options like the moltex reactor is great. Liquid metal fast reactors can be good, but using sodium as a coolant turned out to be a PITA. Lead cooled ones have a large number of advantages

Not true, no need for Th,but we can burn it in IMSR,but doesn't have any benefits.

@@BosonCollider Lead creates long lived activation products...that's why the west never seriously went that path. It creates another long term waste stream.

Russia and France reprocess the fuel at apparently-economical costs, though.

Russia, France, Japan, China and possibly Korea reprocess spent fuel, the UK used to. The mixture is denatured as result of it its residence time in the core, the longer it is irradiated, the more higher actinides accumulate and the plutonium isotopes are very difficult to separate. FWIW the CANDU is almost ideal for making weapons, like the RBMK the fuel can be removed while the reactor is operating making it convenient to operate with very low burnup producing almost pure Pu239.

the main reason for the cost, and the fact that some countries don't reprocess, is regulatory and legal restrictions. If those are sanitised and turned into pragmatic regulations it becomes quite economical while remaining safe (in fact it'd become more safe).

it happends,.. US, Brittain, France, Russia and Japan are reprocessing fuel,.. (well, whit exception of Japan they needet reprocesing capacities for Nuclear weapons program, so if facility already exist why not use it) for others proces is not cost effective att,.. but that does not mean they will not start doing it once it will be.

@@ValExperimenter Japan and Germany asks France to reprocess their spent fuel. ( well used to ask in Germany case ) and don't worry the Weapon Grade Isotopes of Pu and U are separated... before the remaining is sent back to it's original country. ( It's not as if we didn't build that whole recycling system without a reason beyond being able to reuse used nuclear wastes... )

That is just plain false. Properly designed SFRs with metal fuel have a far higher negative temperature coefficient of reactivity than either a LWR or HWR using oxide fuels (nearly every commercial plant on the planet) regardless of if SFRs are running HALEU or mixed Pu/U/Zr fuel types. The EBR-II reactor demonstrated this completely passive safety feature twice in the mid 80s running at full power by disabling the safety systems and removing the power to the primary coolant pumps (test 1) and then the generator heat sink (test 2). In both cases as the fuel, coolant and reactor vessel heated up, the reactivity dropped dramatically and the reactor slowed to an idle with zero damage to the reactor or fuel. This is fully documented in published papers and was even recorded on video.

i thing liguid salt is better coolant option then Sodium, but i bet nuclear engineers woud convince me othervise,... Sodium fast reactors are nothing new, its proven, working concept.

My question is if they are not cost-effective why build them? Why not use the money to build PV, wind and storage to get more power faster and cheaper? Even CANDU reactors are not as fast to build as PV, wind and storage.

Steve Irwin I agree with you assessment of the situation. The CANDU's are a proven design, I'm surprised a SMR CANDU hasn't been offered! Say a 100-200 MWe model. The DUPIC layout for burning spent LWR fuel could make these SMR's units little sports cars with an average 1.5% fissile material content. In addition the CANDU layout is way more flexible for other uses in making useful Isotopes like C0-60 or Mo-99. LWR really can't preform this task because of the pressure vessels. The making of Medical Isotopes would be a very profitable side line. In addition AECL did allot of prototype work on Organic coolant for CANDU's. This would move the thermal efficiency from the high 20's to the mid 30's. This was done at Whiteshell WR-1.

CANDUs are great reactors and IMO the best of their generation, but fail safe might be a bit overboard as it means there CANNOT be an accident. We have had fuel melt in CANDUs, although so far it has tended to affect only a few fuel channels which causes an expensive fix, but not a disaster. However we do have a whole lot of zirconium and water together and that needs to be actively managed. The goal with the new designs is to make it virtually impossible to overheat the reactor vessel based on physic AND to make all the nuclear materials at or very near atmospheric pressure which along with a few other features is inherently safer as it doesn't require safety systems to be engaged (i.e. no moving parts). No energy source is 100% safe, not even renewables and all designs have pros and cons and CANDU is no exception, though at the time, they were exceptionally good...:)

Liquid sodium doesn't "release it's own O2". It is a pure metal. It needs a source of O like air, or water which it can release the O from. In reactors that are properly designed, the primary sodium is in a single piece capped stainless steel pool covered by argon and there is no water in the reactor building. The only pipes are in the top cap and argon is heavier than air, so it just lays there like a blanket. Liquid sodium is 100% compatible with stainless steels used in the reactors (i.e. no corrosion). A secondary sodium loop which is never in contact with the fuel moves the heat out so that if you have a leak, it is an industrial accident, not a nuclear one.

And was proven as a working power plant (Damn that Nixon nixing!)

@@chrisbraid2907 as far as I know it was shutdown because you cant make weapon plutonium out of it or something like that

Why might one introduce water into the medium? The more conventional molten salt designs do not obviously advocate this, and instead suggest that this were an unnecessary further avenue of preventable potential corrosion.

Different project. You are referring to the thorium LFTR reactor and he is talking about a conventional uranium breeder reactor. What connects them is the use of liquid salt as a coolant . these uranium based reactors are a nightmare when it comes to controlling the production of weaponizable materials like plutonium, as he points out without comment. Indeed, it was exactly the reengineering of a CANDU reactor sold to India they gave that country the fuel supply for its atomic weapons program. This was a huge blow to the CANDU program at the time, and setback Canada’s reputation in the international community for decades. The whole point of modular small reactors is it to be mass produced and become essentially a traded commodity. Given that the primary obstacle for most countries to creating a nuclear weapons program is the refinement of uranium into plutonium, you can be very sure that as this technology spreads, it will get into the wrong hands or it will be re-engineered by some states to sell weaponizable material on the open market to rogue states and terrorist organizations. In most ways this is the absolute worst option available for the renaissance of nuclear energy. It’s very likely that atomic energy is the key to controlling climate change, but this replaces one problem with another one. The thorium technologies that were approved at Oak Ridge 40 or 50 years ago, show huge promise, cannot be Weaponized, and have the same or higher inherent passive shut down capabilities and zero pressure processes, but they don’t suit existing companies who make the majority of their money on the supply of fuel to the nuclear industry, rather than the supply of the reactors themselves . Thorium is far more abundant, easier to handle, and lower cost than uranium. Ask yourself the question.

They referred to the EBRII, the oak ridge reactor was the MSRE anyway the former is a sodium cooled fast breeder reactor, the latter a salt cooled and fueled graphite moderated thermal reactor.

@@danieldonaldson8634 Who's word are you taking that the Th fuel cycle cannot be weaponized? It certainly can be and molten salt reactors are the easiest way to do it. Papers published from LLNL stated this while MSRE was being performed, although proponents who stand to make money if it is adopted ignore this. While the U/Pu cycle may be better than the Th cycle for mass production, you don't need a huge and detectable PUREX plant for Th->U233. It is the second best bomb material according to LLNL, ahead of U235, but not quite as good as Pu239 for implosion devices.

Bahahahahahahaha best my a$$

Actually they were constructed all over the world starting in the 50s... but they had a huge drawback : it's hard as hell to separate Uranium Isotopes and a tiny fraction of the wrong one just make the whole lot useless... That's also what killed Thorium reactors. In the 50s/60s the important thing was to produce as much as possible of the Weapon Grade U Isotope and Pu to make bombs.

@@tenalafel Got it in one, people are grossly misinformed that the purpose of civil nuclear power generation was power generation. The entire nuclear industry focused on producing feedstock for nuclear weapons.

Russia/USSR built the first commercial plants, but the first fully successful prototype SFR was EBR-II in the US, which ran for 30 years generating power for Argonne National Labs from 65, long before the BN series.

@@davidcullen4996 That is just BS in most cases. The US weapons grade material was produced in dedicated military reactors, not commercial ones. The burnup in civilian reactors in most cases is too high to easily make weapons grade materials due to a bad isotope ratio. Same applies to nearly all western countries. Much easier and cheaper to make the stuff in dedicated facilities.

@@richardbaird1452 Hey! I'm not sure about the reactors in the west, but in the USSR at least, most civilian reactors were designed to produce weapon grade Pu-239 along with their function of generating electricity. In fact the RBMK reactors at Chernobyl were also designed for this purpose. I've heard that this hampered the investigation after the Chernobyl nuclear disaster since the military classified certain aspects of the designs of these reactors since they were involved in weapons production. (FYI I'm NOT saying this after watching the HBO miniseries about Chernobly, I've actually read quite a few articles about this. Though those articles need not be 100% accurate so take the info with a grain of salt.)

Thorium is far less proliferation resistant than many have been led to believe (mostly by people who want to make money developing them). There are LLNL papers that describe how to make weapons material from Thorium MSRs and the material is rated second only to plutonium (i.e. it is better than weapons grade enriched U235). They also note you don't require huge PUREX facilities to do it, so in a way they are less proliferation resistant. What is needed for the north is small modular reactors, but they don't need to be Molten Salt or Th based...that is simply a choice and there are pros and cons to each design.

We had Super Phenix in France... but the Greens managed to kill it before it was able to prove the full scale concept in the West. ( Fast Neutron Breeder reactor, Full Nuclear Power Plant Scale )

3-mile island, Chernobyl, Fukushima.