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A Nuclear Startup Will Fold After Failing To Deliver Reactors That Run on Spent Fuel (technologyreview.com) 185

Posted by msmash from the end-of-road dept.
Transatomic Power, an MIT spinout that drew wide attention and millions in funding, is shutting down almost two years after the firm backtracked on bold claims for its design of a molten-salt reactor. From a report: The company, founded in 2011, plans to announce later today that it's winding down. Transatomic had claimed its technology could generate electricity 75 times more efficiently than conventional light-water reactors, and run on their spent nuclear fuel. But in a white paper published in late 2016, it backed off the latter claim entirely and revised the 75 times figure to "more than twice," a development first reported by MIT Technology Review. Those downgrades forced the company to redesign its system. That delayed plans to develop a demonstration reactor, pushing the company behind rival upstarts like TerraPower and Terrestrial Energy, says Leslie Dewan, the company's cofounder and chief executive. The longer timeline and reduced performance advantage made it harder to raise the necessary additional funding, which was around $15 million. "We weren't able to scale up the company rapidly enough to build a reactor in a reasonable time frame," Dewan says.
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A Nuclear Startup Will Fold After Failing To Deliver Reactors That Run on Spent Fuel More

A Nuclear Startup Will Fold After Failing To Deliver Reactors That Run on Spent Fuel

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  • Why is anyone wasting their time on this when there's thorium?

    • Re:Where's thorium? (Score:5, Insightful)

      by alvinrod ( 889928 ) on Tuesday September 25, 2018 @12:52PM (#57373798)
      Being able to reprocess spent nuclear fuel means that there's less of a storage issue for nuclear waste.

      • Re: (Score:2)

        by orlanz ( 882574 )

        But I thought there were already "breeder reactors" that did this. How was this design different from them?

        • Re: (Score:2)

          by Anonymous Coward

          Four issues : Cost, oversight, nuclear weapons capabilities, and transportation logistics. Cost ought to get two slots, to signify how much of an issue it actually is. The others could be solved at great cost. The rub, renewables are cheaper.

          Nuclear isn't going to disappear but the idea of expanding it "on a budget" to meet the world's local power needs while wasting abundant clean, cheap renewable energy just doesn't make actual real-world business sense.

        • Re:Where's thorium? (Score:5, Informative)

          by ShanghaiBill ( 739463 ) on Tuesday September 25, 2018 @04:26PM (#57375086)

          But I thought there were already "breeder reactors" that did this. How was this design different from them?

          Old fashioned breeder reactors turn U-238 into plutonium. Although plutonium can be used as reactor fuel, it can also be used to make bombs. Furthermore, these reactors use fuel rods, and pressurized containers, and have the same complexity and safety problems as LWRs.

          What makes this reactor different is that it doesn't make plutonium, it burns the fuel that in breeds in situ so no extra expensive reprocessing is needed, and it is an inherently safe design: It can't have a "meltdown" since it is already liquid, and it is not pressurized.

          That is the theory. In practice, molten salt reactors don't have a very good track record.

          Molten salt reactor [wikipedia.org]

      • Thorium is where it should be, ignored (Score:4, Informative)

        by rahvin112 ( 446269 ) on Tuesday September 25, 2018 @02:07PM (#57374218)

        Processing spent fuel as you suggest is extremely dirty and generates about 10x the amount of original waste, most of it highly radioactive.

        People forget the US tried to reprocess fuel for a while, the location is a radioactive superfund site.

        • Re: (Score:3, Informative)

          by thegarbz ( 1787294 )

          Sorry but that's a lot of bollocks. Reprocessing does not generate 10x the amount of original waste. The final waste product is still very much the same the only difference is there's a hell of a lot of additional energy that is able to be extracted in the process which means per unit energy generated the final waste product is significantly reduced.

          There's a reason sensible nuclear nations reprocess fuel. Of course the USA's interest in reprocessing was to extract plutonium for weapons manufacture, and tha

          • Re: (Score:3, Informative)

            by rahvin112 ( 446269 )

            Do you believe "reprocessing" is this magical process whereby the constituent elements are magically separated using no additional input materials?

            To reprocess nuclear fuel you have to chemically separate the various elemental constituents. That chemical processing exposes the processing chemicals to the intense radiation of the fuel and creates radioactive fluids and the separative elements added to the process, often at far higher quantities. In 1966 when the US tried this the Company doing so disposed of

            • Re: (Score:2)

              by MobyDisk ( 75490 )

              Just because someone polluted the environment in 1966 doesn't mean we should abandon the technology forever. This kind of thinking is exactly why our nuclear arsenal is 50 years old.

              • So just because we tried it, polluted a huge area and generated a couple hundred metric tons of contaminated material it's all good, we just didn't do it right that time?

                Color me skeptical that in any system where cost is a consideration you're going to likely end up with a superfund site.

                Reprocessing is hard and it generates a lot of waste material used in the reprocessing, that's just a fact of using chemical seperation processes. Is it worth generating 100 Tons of highly radioactive material to reprocess

                • So just because we tried it, polluted a huge area and generated a couple hundred metric tons of contaminated material it's all good, we just didn't do it right that time?

                  Yes. This is demonstrably true because other countries have managed to do reprocessing just fine.

                • Re: (Score:2)

                  by MobyDisk ( 75490 )

                  Color me skeptical

                  Fine.

                  Reprocessing is hard and it generates a lot of waste

                  Agreed.

                  Is it worth generating 100 Tons of highly radioactive material to reprocess a ton of nuclear material?

                  NOW we are having a discussion! :-)

                  It might be worth doing. The entire point of reprocessing is to produce highly dense highly radioactive material. It is easier to use and store than less dense less radioactive material. I do not know if it is worth it. But I DO know that freezing science in the year 1966 just because of their environmental policies is counterproductive.

                  So just because we tried it, polluted a huge area and generated a couple hundred metric tons of contaminated material it's all good, we just didn't do it right that time?

                  We sure didn't! 50 years ago the manufacture of steel dumped toxic chromium into waterways. Manufacturing pressure-treat

                  • NOW we are having a discussion! :-)

                    It might be worth doing. The entire point of reprocessing is to produce highly dense highly radioactive material. It is easier to use and store than less dense less radioactive material. I do not know if it is worth it. But I DO know that freezing science in the year 1966 just because of their environmental policies is counterproductive.

                    Spent LWR fuel rods are are dense highly radioactive material. With the current 50 GWd/tonne burn-up rate each rod is about 1% plutonium and 5% fission products in a sealed solid package, very stable.

                    Using current dry cask storage practices all the spent fuel over the (extended) lifetime of all U.S. power reactors ever operated would fit in in 100 acre storage area. And since we are storing it that way right now, this costs nothing extra.

            • In 1966 when the US tried this

              I'll take the French, UK, and India still doing it over your isolated example of a single USA failure. Interesting that you hold up the West Valley which operated only for a couple of years as the USA example, instead of e.g. Svahnnah River which was close to 10 times the reprocessing capacity, operated for 50 years, was closed less than a decade ago, and by your accounts should have flooded half of the country in nuclear waste by now ... but hasn't.

              • ... instead of e.g. Svahnnah River which was close to 10 times the reprocessing capacity, operated for 50 years, was closed less than a decade ago, and by your accounts should have flooded half of the country in nuclear waste by now ... but hasn't.

                Yeah, lets look at Savannah River Site [srs.gov]:

                High-activity liquid waste is generated at SRS as by-products from the processing of nuclear materials for national defense, research and medical programs. The waste, totaling about 36 million gallons, is currently stored in 49 underground carbon-steel waste tanks grouped into two “tank farms” at SRS.

                36 million gallons of high level liquid waste, prone to leaking and chemical reactions. Each of these one tank farm covers an area of 20 acres, or 40 acres total.

                OTOH the entire lifetime output of all power reactors operating or ever operated in the U.S. could fit into a 100 acre dry cask storage field with generous cask spacing.

    • Re: (Score:2, Interesting)

      by Anonymous Coward

      Why are nuclear fanboys still pushing debunked Thorium breeder technology that has been relegated to a scientific curiosity? The new messiah is SMR's.

      http://www.world-nuclear.org/information-library/nuclear-fuel-cycle/nuclear-power-reactors/small-nuclear-power-reactors.aspx

    • Why is anyone wasting their time on this when there's thorium?

      Their design does use thorium. The base salt is thorium fluoride. You heat up the salt till it melts, and then just mix in the nuclear waste, hook it up to a turbine, and presto, energy too cheap to meter.

      Thorium salt reactors work GREAT in theory, and nerds tend to love them. In reality, there are ... problems.

    • Re: (Score:2)

      by Spirilis ( 3338 )

      Many of the processes required to utilize thorium (which is fertile, not fissile, but fertile at slow-spectrum which is interesting) can be applied to 238U at fast spectrum instead. EBR-II (IFR) demonstrated this. The main advantage of thorium is it's an abundant reserve source for making 233U (+232U, which makes it difficult to handle) if we can't find uranium anymore.

      IIRC, a startup called Oklo is looking at reviving the EBR-II technology at very small scale, ~1-2MW, basically diesel generator replaceme

      • Re: (Score:2)

        by wagnerer ( 53943 )
        The glut in the uranium market doesn't help. Why go to advanced technologies when basic uranium fission is so cheap.

    • Yes, however there is also abundance of uranium and ready facilities to prepare uranium based fuel.
      In detail, thorium is prevalent on land whilst uranium in oceans (estimated more in total than thorium) additionally considering existing infrastructure and equipment to mine/process and prepare power plant ready fuel rods and all the paperwork related to build a new power plant it is simply cheaper to build something close to existing solutions then to push for a novelty. Some government studies and research

  • So What? (Score:5, Interesting)

    by atomicalgebra ( 4566883 ) on Tuesday September 25, 2018 @12:50PM (#57373790)

    There are around 50 nuclear startups designing 4th generation reactors. Some were always going to fail. In fact most will probably fail. Some will succeed though.

    NuScale is the closest to market. Their design has already passed NRC phase 1 review, and it has been certified as meltdown proof. They will be constructing their first 12 reactors in Idaho for Utah municipalities. Hopefully in a decade they will be mass producing them like airplanes.

    • when the wiki page says gas plants cost $1900/kilowatt [wikipedia.org] vs $5000/kilowatt.... That's the only part I don't get. Is this just building in alternative sources for better grid reliability?
      • NuScale current estimate is $4200/kilowatt. Mass production hopefully will reduce that cost further. Gas is dirty. I do not understand why you do not understand that. Climate change is real. Air Pollution is real. Also gas is expensive for the consumer. Peaking natural gas often goes for $1000 MWh. Compare that to Diablo Canyon which sales electricity at $27 MWh (1/3 the average cost).

        • Gas is dirty. I do not understand why you do not understand that. Climate change is real. Air Pollution is real. Also gas is expensive for the consumer.

          Have you met the average consumer? If you tell them that this "clean energy" will only cost them twice as much most won't approve. It has to be directly cheaper then natural gas. For us engineers that's nuts, but then again I accepted long ago that most people are stupid and short sighted.

          As a resident of Utah I enjoy pretty cheap power and solar is a very viable option with about a 10-year payoff rate. So it'll be a hard sell to convince people that it's worth the risk of putting in a Nuclear Reactor anywh

          • Have you met the average consumer? If you tell them that this "clean energy" will only cost them twice as much most won't approve.

            Eventually the USA will join the 1st world and stop ignoring externalised costs, the "average consumer" will actually pay for the real cost of electricity and not only opt for the green choice, but maybe start doing something to actively bring the horrid energy consumption per household of the USA down to more reasonable levels.

            • Nice USA bash. "America is the suck." HOWEVER the 1st world includes the European Union and Japan, both of whom are shutting-down nuclear plants (after the 2011 earthquake released a bunch of radioactivity).

              • Nice USA bash. "America is the suck."

                No. I don't bash anyone. I do criticise however. The USA has a fascination with energy waste mostly driven by the insanely low cost of energy. It's the fundamental economic principle behind it. Humans the world over will opt for comfort and convenience. Just in much of the world where energy is taxed to clean up the externalised costs it's more expensive so people take more care of it.

                HOWEVER the 1st world includes the European Union and Japan

                Countries where cars get significantly higher mileage and are used far less (cost of gasoline 4x higher than the USA). And b

          • Re: (Score:2)

            by mspohr ( 589790 )

            Wind and solar power sources are cheaper than nuclear, coal, NG, etc. Try telling people they need to pay more for nuclear and fossil fuel power.

        • Re: (Score:2)

          by mspohr ( 589790 )

          Solar and wind are about $1000/kilowatt so much cheaper (and getting cheaper every day).
          Solar and wind energy costs about $20/MWh so much cheaper (and getting cheaper every day).
          Batteries to smooth production and protect the grid pay for themselves so no extra cost.
          Solar and wind are proven technologies which can be installed in running in less than a year compared to nuclear research projects which may or may not produce electricity decades from now. Why even try?

          • Solar and wind have capacity factors of 30%. They do not function 100% of the time. Solar produces nothing when demand is at its highest(see duck curve). If you count the cost of batteries the price will explode. If you take into account how much energy nuclear generates it much more competitive. If California or Germany spent their resources on new nuclear instead of renewables they would already be 100% clean.

            Batteries to smooth production and protect the grid pay for themselves so no extra cost.

            Nope. You are just looking at that tesla load balancing battery in Australia. Scale that u

            • Re: (Score:2)

              by mspohr ( 589790 )

              Nuclear is 100% clean if you don't count the nuclear waste.
              It's not just Australia, batteries pay for themselves everywhere. Nobody needs 100% grid storage anywhere.
              Nuclear is proven to be very expensive. Long lead times, overruns on costs. Even old nuclear plants can't compete with wind and solar.
              Climate change is real. Wind, solar and batteries are proven technologies which can be installed in less than a year. Why waste money on nuclear (Votgle, I'm looking at you) when you can have a solution this year,

              • Then why has Germany failed to reduce greenhouse gas emissions from electricity production? They have spent a quarter of a trillion euros on renewables with very little to show for it(except of course the highest energy prices in Europe). Their electricity grid pollutes 10x as much as France does.

                Nobody needs 100% grid storage anywhere.

                If you do not have 100% grid storage it means you are running on something other than renewables. In germany it is coal, in California it is natural gas. We should be using nuclear since it is cleaner than co

                  • Citing Jacobson eh? You do know he is a snake oil salesman? The National academy of sciences has discredited his work. Read the article here [pnas.org]

                    In particular, we point out that this work used invalid modeling tools, contained modeling errors, and made implausible and inadequately supported assumptions. Policy makers should treat with caution any visions of a rapid, reliable, and low-cost transition to entire energy systems that relies almost exclusively on wind, solar, and hydroelectric power.

                    Jacobson is a con man.

                    • Re: (Score:2)

                      by mspohr ( 589790 )

                      If you are familiar with that hit piece from people funded by Exxon, Ford Motors, and other fossil and nuclear fuel advocates, etc. then you should also be familiar with Jacobsons reply.
                      http://www.pnas.org/content/11... [pnas.org]

                    • Yeah his reply was an ad hominem attack followed by a lawsuit. Filing lawsuits against other scientists is why I started calling him a snake oil salesman. His reply did not address any of the criticism of the original article. Jacobson's and your opposition to nuclear energy is emotional.

                      MIT scientists just released analysis saying we will need nuclear energy. Climate scientist James Hansen called Nuclear energy "the only viable path forward on climate change." Maybe you should try to understand why

                    • Re: (Score:2)

                      by mspohr ( 589790 )

                      If only nuclear could get its act together, it might be viable. As it is, it's just too expensive to matter. The latest nuclear fiasco is the Votgle plant in Georgia which is on the precipice of being cancelled. It started as a $7 billion project and is now up to $32 billion with no end in sight (and, of course, many years late).
                      The latest nuclear darling NuScale, is thinking it might be able to start producing electricity ten years from now (and no word on costs).
                      We can't wait ten years to start producing

                    • Actually $28 billion which comes out to $14 billion per reactor. Not a bad deal considering the reactors will last 100+ years. Of course the Chinese built an AP 1000 in five years so it can be done. Nuclear energy should be thought of as a public works projects and should be subsidized(like solar and wind). The cost of the reactors in insignificant when compared to the cost of climate change or the costs of batteries.

                      NuScale is forced to wait years before they are even allowed to start construction.

      • when the wiki page says gas plants cost $1900/kilowatt [wikipedia.org] vs $5000/kilowatt.... That's the only part I don't get. Is this just building in alternative sources for better grid reliability?

        Grid reliability and fuel diversity is part of the equation, but nuclear can have lower operating costs due to the extremely cheap fuel. Now, a nuclear plant does require far greater staffing than a combustion plant, but that doesn't eat up all the savings of cheap uranium fuel.

        A large nuclear power plant with efficient staffing is a huge money maker in most (not all) parts of the US and the world.

    • Hype (Score:3, Interesting)

      by sjbe ( 173966 )

      There are around 50 nuclear startups designing 4th generation reactors. Some were always going to fail. In fact most will probably fail.

      No there are lots of them CLAIMING to be developing new reactor designs. Some of them might actually be working on the problem even. Curiously we've seen zero of these actually make it to market.

      Some will succeed though.

      There is no guarantee of that.

      NuScale is the closest to market.

      Maybe. Best info I can find says they hope to have an operational reactor in 2024 [nuscalepower.com] and that was their projection in 2013. That means optimistically they might have something to show 6+ years from now. Not exactly cause for excitement.

      Their design has already passed NRC phase 1 review, and it has been certified as meltdown proof.

      NRC phase 1 review is a "Preliminary Safety Evalu [nrc.gov]

        • U.S. Nuclear Regulatory Commission Approves Key Safety Aspect to NuScale Powerâ(TM)s Advanced Reactor Design

          From the fine press release, "The U.S. Nuclear Regulatory Commission (NRC) has concluded that application of NuScale Powerâ(TM)s novel safety design approach eliminates the need for class 1E power for its small modular reactor (SMR)." OK, so they've signed off on one aspect of the design. The PR goes on to say that "the NRCâ(TM)s final report approving the design is expected to be complete by September 2020." That was approval of a feature, not the design. Get back to use when they have design app

      • Re: (Score:2)

        by AmiMoJo ( 196126 )

        Anyone claiming that something is "meltdown proof" is a charlatan.

        • Yet we have had provable meltdown proof reactors since the 1980's. See Experimental Breeder Reactor II [wikipedia.org]

          • Re: (Score:2)

            by AmiMoJo ( 196126 )

            It didn't meltdown under one specific test. That doesn't make it meltdown proof.

            • Yes it does. They intentionally tried to cause a meltdown and failed. The scientists at that lab have said repeatedly that it could not meltdown.

              • Re: (Score:2)

                by AmiMoJo ( 196126 )

                They tried one method to make it melt down. You may recall that the Chernobyl disaster was due to some idiot running an experiment, not just loss of the cooling system as they tested.

                • There were multiple tests. Shutting down the cooling system was just one of them. It cannot meltdown. They proved it. The reactor was designed to have a negative thermal coefficient of reactivity making meltdowns impossible. Comparing Chernobyl to the EBRII or any western reactor is disingenuous. It is a powerful rhetorical tool which is why you are using it as a crutch in this debate. It does mean you are correct.

                  • It cannot meltdown. They proved it. The reactor was designed to have a negative thermal coefficient of reactivity making meltdowns impossible.

                    No they did not prove it for all conceivable circumstances. They proved it for SOME conditions and methods with a specific reactor design. Your argument assumes that there is no chance of that reactor design being incorrectly engineered, no chance of improper construction or maintenance, no chance of external damage (natural disasters, war, etc), and that in all other ways the reactor cannot be compromised to induce that failure mode. And even if a meltdown were indeed impossible that's not the only poss

          • Yet we have had provable meltdown proof reactors since the 1980's. See Experimental Breeder Reactor II

            You should read your link. They did tests to see if the reactor would not melt down under specific circumstances. This is a far different thing than proving it is "meltdown proof" under all circumstances. Passive fail-safe cooling systems are a good thing but they only solve some of the dangers presented by fission power plants. Furthermore just because they are in place does not mean they still cannot fail due to flaws in engineering, construction, maintenance, natural disasters, or physical damage.

            You

            • If you listen to the scientists at that lab they said the EBRII could not meltdown under any circumstances. They intentionally tried to cause a meltdown and failed. You are overstating the risks of nuclear energy

              • If you listen to the scientists at that lab they said the EBRII could not meltdown under any circumstances.

                Find me a quote of any scientist claiming that meltdowns were impossible under "any circumstances". That's just obviously bullshit unless you are talking about specific conditions. It assumes no engineering flaws, no manufacturing flaws, proper maintenance, no external disasters or attacks, etc. They did some tests which the reactor passed but that isn't remotely the same thing as being safe in all conditions. Furthermore a meltdown is NOT the only failure mode of concern. There are a lot of still very

                • Find me a quote of any scientist claiming that meltdowns were impossible

                  Watch this silly https://www.youtube.com/watch?v=Sp1Xja6HlIU [youtube.com] Goto 4:25 to hear him say it cannot meltdown. Suck it.

                  insurance companies

                  Insurance companies. So your argument against solving climate change is wall st made a bad bet 50 years ago? That is silly. If wall st insurance let energy companies by insurance they would have made nothing but money for decades.

                  Even if you eliminate meltdowns as a failure mode entirely that doesn't mean nuclear is 100% safe.

                  Nothing is perfect, but if you consider current nuclear is safer than solar and wind. That means next generation nuclear is safer than just about anything els

    • There are around 50 nuclear startups designing 4th generation reactors. Some were always going to fail. In fact most will probably fail. Some will succeed though.

      NuScale is the closest to market. Their design has already passed NRC phase 1 review, and it has been certified as meltdown proof. They will be constructing their first 12 reactors in Idaho for Utah municipalities. Hopefully in a decade they will be mass producing them like airplanes.

      I challenge you to back that "50 nuclear startups" with anything.

      NuScale does at least exist (unlike the just shuttered Transatomic) and has done enough work to pass a design review, and to get a license to start looking for sites at the Idaho National Laboratory (but not for any actual site), and so yes, this is farther along than any of the others.

      But I went Googling to check whether these projects existed anywhere but as NuScale press releases on their own website -- like on the websites of the purported

  • Physics wins again! (Score:1)

    by Anonymous Coward

    The momentum of the regulatory structure is impressive.

  • First we had Rocket Jesus, a.k.a Elon Musk, and now we have Nuclear Jesus, a.k.a Leslie Dewan. Although, molten salt does remain (eventually) a viable idea.
  • Comment removed based on user account deletion

    • eh, it's technically possible (and a done deal) to use spent fuel or even depleted uranium or natural uranium in certain types of reactors, and to get many times the energy out of said fuel than a PWR could do.

      • it's technically possible (and a done deal) to use spent fuel or even depleted uranium or natural uranium in certain types of reactors, and to get many times the energy out of said fuel than a PWR could do.

        Yes, but it requires special equipment and special handling, and it still can't be done cost-effectively.

      • Comment removed based on user account deletion

  • The DUPIC fuel cycle allows for the direct reuse of PWR fuel in CANDU heavy water reactors. The only thing required is mechanical modification of the PWR fuel bundles so that they fit into the CANDU fuel channels.

  • When asked who was responsibility for the discrepancy between 75x and 2x, the lead scientist Michael Bolton confessed, "Oh shit, I always do that! I always mess sup some mundane detail." :P

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