Nobody is saying it, but the advent of artificial intelligence and machine learning may be springboarding the increased intensity of the competition for nuclear fusion – which many are now saying is far less than “30 years away.” The burning question among the few who are fully aware of the stakes in this race is “Who will get there first?” coupled with “Does first matter more than best?”
The greatest obstacle to fusion supplying the world with limitless electricity is learning how to maintain a balance between magnetic confinement and the severe heat (100 million degrees Celsius). Fusion produces cleaner energy than fission (its only byproducts are helium and other greenhouse gases – not radiation), and its fuels – deuterium and tritium – can easily be sourced from seawater and lithium. Scientists today are trying multiple ways to skin this cat.
Serious consideration of nuclear fusion began in the 1930s with the discovery of tritium by a research team led by experimental physicist Ernest Rutherford, who had earlier collaborated with Niels Bohr in the discovery of the neutron. In 1938, University of Michigan scientist Arthur Ruhlig proposed that deuterium-tritium fusion occurs with a very high probability when the two are brought into close proximity – but then World War II put fusion research into the freezer.
The most celebrated event in the revival of fusion research came at the Geneva Superpower Summit in November 1985, when General Secretary Mikhail Gorbachev proposed a collaborative international project to develop fusion energy for peaceful purposes. A year later the European Union (as Euratom), the U.S., Japan, and the Soviet Union agreed to jointly pursue the design for a large international fusion facility they called ITER (the way).
Fast forward to 2001. After 13 years of conceptual design work and detailed engineering design work, the final design for ITER was approved. Two years later the People’s Republic of China and the Republic of Korea joined the project, with India coming on board in 2005, the year that ITER members agreed to site the gigantic project near Aix-en-Provence in France. A year later, the members formally created the ITER Organization with the goal of building the ITER Tokamak, the world’s most advanced magnetic confinement fusion experiment.
Last November, the ITER Organization updated its baseline proposal to prioritize a “robust start” to scientific exploitation with a more complete machine than initially planned – with a divertor, blanket shield blocks, and other key components and systems. These are to be in place in time for the first operational phase for the tokamak, Start of Research Operation.
This first phase features hydrogen and deuterium-deuterium plasmas that culminate in operating the machine in long pulses at full magnetic energy and plasma current. The goal is to achieve full magnetic energy by 2036 and the start of the deuterium-tritium operation phase in 2039 (rather than 2033 and 2035, as originally planned).
Meanwhile, both public and private (and public-private) entities have not sat around waiting for ITER to generate limitless energy in southern France. Instead, there is a growing race among nations and corporations to find quicker ways to turn straw into gold – or rather hydrogen into electricity and more. Western nations, already left in the dust on lithium-ion battery and other technologies and supply chains by the Chinese, now fear that China may win this race too.
Just last month China announced that its Experimental Advanced Superconducting Tokamak (EAST) – its artificial sun — had broken its own record by confining plasma for nearly 18 minutes, longest in the world to date. That might sound like a small step toward the mandatory requirement that a fusion device maintain stable operation at high efficiency without interruption to continuously generate electric power.
That is one reason that a recent report from the Massachusetts Institute of Technology warned that “The U.S. and other Western countries will have to build strong supply chains across a range of technologies in addition to creating the fundamental technology behind practical fusion power plants” to stay in the race at all. One of China’s overall strengths, and the West’s weaknesses, has revolved around investment in supply chains and scaling up complex production processes.
Until recently, the MIT Report says, the U.S. and Europe were the dominant public funders of fusion energy research and home to many of the world’s pioneering private sector fusion projects. But in the past five years, China has upped its support for fusion energy to the point it threatens to dominate the industry.
To compete, the U.S. and its allies and partners must invest more heavily not only in fusion itself—which is already happening—but also in those adjacent technologies that are critical to the fusion industrial base. The MIT Report says that China already has leadership in three of the six key industries needed for constructing tokamaks — thin-film processing, large metal-alloy structures, and power electronics. The West has little time to cash in on its opportunity to lead in cryo-plants, fuel processing, and blankets — the medium used to absorb energy from the fusion reaction and to breed tritium.
China is the world leader in thin-film, high-volume manufacturing for solar panels and flat-panel displays, with the associated expert workforce, tooling sector, infrastructure, and upstream materials supply chain needed to manufacture rare-earth barium copper oxide (REBCO) superconductors – the highest performing materials for use in fusion magnets. China’s high-speed rail industry, renewable microgrids, and arc furnaces give it an edge as well in large-scale power electronics, and Chinas’ manufacturing capacity and metallurgical research efforts position it well to outcompete the world in specialty metal allows machined for fusion tokamaks.
But are the Europeans and Americans sufficiently focused – and willing to commit – to staying in the race and playing to win? As Euractiv reported this week, Christophe Grudler, an influential member of the European Parliament’s industry committee, is hardly sanguine.
Grudler stated before a gathering of politicians and stakeholders at a Fusion for Energy event that “There is a lack of political leadership [at the European Commission] when it comes to nuclear energy in Europe…. Only 2% of the global amount of fusion investment is currently going to Europe, while 75% is going to the U.S.”
Seconding his concern, Massimo Garribba, deputy chief of the Commission’s energy department, said the intent is there for fusion but there needs to be a larger strategic focus that goes beyond financing. There is plenty of money and enough wonderful people, but “you don’t have an ecosystem of facilities which actually drives toward having a functioning system at the end of the day.”
As for the U.S., the Department of Energy last November released its DOE Fusion Energy Strategy 2024, the second step in its comprehensive effort to work with the private sector to accelerate “the feasibility of commercial fusion energy.” The DOE’s own plan tacitly admits that the U.S. is playing in catch-up mode.
Several U.S.-based private sector projects are under way, including those reliant on stellarators rather than tokamaks, but none have confined plasma for anything near 18 minutes, and there are huge questions about the supply chain needed to support a fusion industry. Regulatory reforms on the way may help – but what happens if today’s protesters turn on the nuclear industry?
Duggan Flanakin is a senior policy analyst at the Committee For A Constructive Tomorrow who writes on a wide variety of public policy issues.
This article was originally published by RealClearEnergy and made available via RealClearWire.
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Fusion is a very tough nut to crack. I am not sure that any breakthrough will come from ITER.
What’s needed is a genius idea on how to contain the reaction that is simple and effective. It may exist, but if so no one knows what it is…
Actually, not so as worded . . . instead, large scale, commercially viable electrical or thermal power generation via sustained fusion is THE hard nut to crack.
One can presently purchase portable IEC (inertial electrostatic confinement) devices that produce neutron radiation as the result of small scale continuous nuclear fusion reactions.
There is even a book in print that discusses these commercial devices and the possibilities they may be scalable to larger size (see https://www.amazon.com/Inertial-Electrostatic-Confinement-IEC-Fusion/dp/B010WFBOMU ).
And there is this from the abstract of “Development of Portable SNMs Detection System with D-D Neutron Source based on Combination of Noise Analysis and Threshold Energy Neutron Analysis Method” (https://ieeexplore.ieee.org/abstract/document/8824330 ):“The D-D neutron source shown in Figs. 1 and 2 is a compact and light-weight portable discharge-type fusion neutron source called IECF (Inertial Electrostatic Confinement Fusion) device. It provides 2.45 MeV mono-energetic neutrons whose production rate is more than 5×10 7 n/s in CW mode without using radioisotope such as tritium. An important advantage of IEC comes from the use of “gas target” and this enables stable high-power operation of IEC devices to produce copious amount of D-D neutrons in a compact system.”
Buy your very own nuclear fusion reactor:
here: https://www.starfireindustries.com/ngen.html ,
or here: https://www.ortec-online.com/products/systems/chemical-weapons-identification-systems/pins3-cw-g2
Mr. Fusion?
/humor
Another tough nut to crack is dealing with the neutrons from the fusion process.
Neutrons are our friend. They allow us to magically turn one element into another, or into a few smaller elements – thus getting rid of undesirable isotopes, with the production of energy as a bonus. D-T fusion is the easiest route available, and it always gives the gift of a neutron. Embrace it. Multiply the neutrons, so we can use otherwise useless isotopes as energy sources. Aneutronic fusion is a fool’s errand.
Coal is much less costly AND available NOW, not pie in the sky
Assume 1800 MW (three x 600 MW), coal plant, turnkey-cost at $10 b
Life 50 years; CF 0.9
Payment to bank, $5 b at 6% for 50 y; $316 m/y x 50 = $15.8 b
Payment to Owner $5 b at 10% for 50 y; $504 m/y x 50 = $21.2 b
Life-time production, base-loaded mode, 1800 x 8766 x 0.9 x 50 = 710,046,000 MWh
O&M escalates at 4%, insurance escalates at 4%, periodic overhauls are ignored
For lower electricity cost/kWh, borrow more money, say 70%
Nuclear has similar economics
Wyoming coal, at mine-mouth $15/ton, 8600 Btu/lb. plant efficiency 40%
Btu/ton = 2000 x 8600 = 17.2 million
Lifetime coal use = 710,046,000,000 kWh x (3412 Btu/kWh/0.4)/17200000 Btu/ton = 353 million ton
Lifetime coal cost at $15/ton = $5.3 billion
Electricity cost = (15.8 + 21.2 + 5.3) x 1,000,000,000/710,046,000,000 = 0.06 $/kWh
The woke elites in Europe and the US are pre-maturely closing, already-paid-for, in-good-working-order, nuclear plants.
The woke elites have banned 1) oil and gas fracking projects, 2) gas/oil pipelines, 3) gas/oil storage systems near power plants, and 4) new energy exploration projects, as part of “leaving it in the ground”
.
The US should not bail out Europe by exporting its valuable coal, oil and LNG.
The US should use them to make more products and services for domestic use and exports.
That way the US would reduce imports and increase exports, which would rapidly decrease our decades of wealth/job-sucking trade deficits, and would employ tens of millions of additional US workers, which would strengthen families and communities.
Good points. We should only be exporting coal, oil and LNG to the extent that we can’t economically use these valuable inputs ourselves for the production of higher order goods, which can then either be consumed or exported, as the case may be. And btw, the term ‘economically’ means that if there are any current domestic regulatory constraints on our use of these resources, e.g., those arising from ‘climate alarmism’, these should be expunged from our laws immediately with extreme prejudice.
Yes, modern coal is my preferred choice: clean, cheap, reliable, plentiful, and, it produces a wonderful byproduct that’s great for greening our precious Earth.
And can be stockpiled thereby avoiding service disruption due to supply issues that gas is vulnerable to.
The ‘tough nut’ to me is something I’ve never heard explained. Once you can create a stable, long lasting magnetically contained 100 million degree plasma bubble, how exactly do you get inside to extract any useable heat energy from it to actually do work?
Not to worry, that’s where ‘AI’ comes in.
/sarc
I stopped reading at “the advent of artificial intelligence”.
If anything ever cracks the fusion nut, it won’t be the current crop of AIs, though they may well produce a large number of gramatically correct documents containing all the appropriate words.
…and filled with made up shit.
AI Advocates won’t admit that AI isn’t a creative or innovative intelligence. All it is, is a giant, fast look-up engine. So all it’s good for is researching quickly the info that is already recorded, and at best recognizing correlations.
We don’t need to “get inside” the fusion reactor we call the Sun to enjoy the benefits of its “usable heat energy” (as radiation) we receive at a a mere distance only 93 million miles away. In fact, life on Earth depends on that energy to “work”.
Magnetic confinement does not work on electrically neutral particles. Neutrons are NOT contained and RADIATE out of the reaction zone.
They hit the wall, are absorbed into the shell and release their kinetic energy, producing thermal energy which will heat a fluid so that you can make steam, etc.
The catch is that the wall material becomes saturated with extra neutrons, those elements then become unstable and decompose, often in ways that make them dangerous. For example, look up Iron. If you add neutrons to the mix, it often ends in a nucleus that decomposes via beta decay, to Cobalt. In this case, it’s not the Cobalt that will kill you, it’s the beta radiation that gets out.
And if you were relying on the Iron in the containment wall being the structural element, how do you think it will perform when large portions are replaced with Cobalt? Especially if the neutrons aren’t flowing outward in a perfectly even spread but instead tend to flow out via one or two main paths. What then…. a localised failure of the containment vessel?
Hmm…. So we create a massive – energy intensive – magnetic bubble to fuse hydrogen at 100 million degrees just so it will whack a bunch of neutrons bullets out of the hot bubble into some kind of wall, and then we capture that impact heat by wrapping the wall with some kind of hi-tech copper coils circulating a fluid to make steam in a heat exchanger?
Must say I’m a little less impressed with this “Fusion is the Future” energy source. Doesn’t seem like that big a leap forward from a nice simple coal-fired boiler.
And good luck coming up with a material that can withstand constant neutron bombardment 24/7 for days on end. Probably just another 20 years away tho.
Many years ago it was ,I believe, Enrico Fermi observed that to utilize nuclear energy all we needed to do was put the sun in a box, but the problem is no one knows how to build the box.
That is still the problem. We should be focusing on efficient, safe fission. We know how to do that.
Ah but the entire point of the fusion delusion is to deflect from doing anything that would actually work.
I remember reading long ago that the containment vessel becomes radioactive
yes becasue all fusion reactions produce a bunch of radiation (the author is confusing radioactive waste with radiation)
You remember correctly, as the D-D and D-T reactions produce neutrons which then activates the conaintment vessel. There are options for aneutronic fusion reactions.
The fusion race heats up,of course, fuelled by burning cash.
Back in the days looney but smart brains pursued the idea of creating a perpetuum mobile…similar futile effort.
Well despite all my scepticism, in case fusion really would succeed…would it free us from all the loons that plague us with birdchoppers and garbage panels…and will it come in time BEFORE all that imposed BS has bancrupted us and ruined the planet?
My short answer has only two letters, guess if you please.
I’ve been hearing for 20 years that there will be commercial fusion generators operating within 5 years. Still waiting. Not holding my breath.
Grok sez $8Billion has been spent on fusion research in the US since the 1950s ($7B in private funding).
I was offered employment performing support of fusion research at both Lawrence Livermore and at Los Alamos National Laboratories (eventually consolidated into the National Ignition Facitity at Livermore) in the early 70s. I recognized my contributions would have been miniscule and lost in the scope of the science and engineering required. I wanted more than a paycheck so I declined.
From the above article:
“Western nations, already left in the dust on lithium-ion battery and other technologies and supply chains by the Chinese . . .”
Ummmm . . . the groundbreaking work toward the invention of the lithium-ion battery is credited to American professor John Goodenough, an acclaimed materials scientist and recipient of the Nobel Prize (with assistance from Japanese researcher Koichi Mizushima). In 1990, their patents on Li ion batteries were licensed to Sony Corporation, and subsequently to other battery manufacturers.
— https://en.wikipedia.org/wiki/John_B._Goodenough
While true, it is the mass production and robust supply chains developed and used by the Chinese that is the point.
Well, whose idea was it to move production to China? Who agreed to teach them our industrial secrets, and allow them to steal what they couldn’t strongarm out of our companies?
Nixon.
And many Presidents since.
yep. let us not forget that Clinton approved LORAL’s sale of missile staging and targetting tech to the chicoms.
I sold my LORAL stock in disgust and lost a bundle in future earnings
Well, the “robustness” of those supply chains from (CCP) China will be severely tested under new trade tariffs to be imposed this coming August 1.
Let’s see what happens then.
I have popcorn and beer at ready.
I take that approach because there is not a damned thing I can do about any of it except watch the shenanigans and be entertained.
“helium and other greenhouse gases”
Since when helium is a greenhouse gas?
Everyone talks funny in that greenhouse.
Send mo money to the pit.
Fusion reactors produce TONS of radiation what they don’t produce is radioactive waste other than the containment vessel …
“deuterium and tritium – can easily be sourced from seawater and lithium”
Deuterium can be sourced from seawater easily.
Tritium can be sourced from lithium, but not easily. Current costs are prohibitively expensive, $30-100k/g, several $BLN for a 1 GW reactor for 1 year). Hypothetically, if fusion already worked, tritium could be produced at lower cost by breading in the reactor, but this is chicken and egg problem.
The south polar region of the Moon may have deposits of Tritium. Put there by the Sun’s solar wind…
Lovin’ that.
BTW, the physical half-life of tritium is 12.3 years . . . so combine that fact with these scientific measurements of tritium contained in the Sun’s solar wind:
“Tritium has been measured, in Surveyor 3 samples, some of which were adjacent to those in which solar-wind-implanted He-4 had previously been measured. Little of the H-3 can be attributed to solar-wind implantation. The upper limit for the H-3/He-4 ratio in the solar wind is four times ten to the minus tenth power and corresponds to a H-3/H-1 limit of two times ten to the minus eleventh power.”
— https://ntrs.nasa.gov/citations/19760049052 , my bold emphasis added
With only one atom of tritium existing per 5e10 atoms of hydrogen in the solar wind, and considering the really short half-life of H-3, it is almost certain that little recoverable tritium exists ANYWHERE on the Moon.
No radiation?
build strong supply chains across a range of technologies
A very modern version of “then a miracle happens”.
I doubt if we can ever master fusion, it is always just out of reach, seemingly close enough to keep trying to reach.
I propose that we will not have fusion energy until we can control gravity.The only relatively stable working fusion reactors in the universe use gravity to control them and even those are not that stable long term. How are the super cooled magnets supposed to stay working with a few billion watts of heat thrown at them since the boiler is outside of the containment system and how well will the metal the magnets are constructed of deal with the neutrons?
Reads like a headline from 1952 — Edward Teller, Andrei Sakharov, phone your offices!
That and this —
From which you’d never guess that the Manhattan Project had anything to do with actual thermonuclear (fusion-based) weapons, and hence to the projects to channel those same processes that occur in bombs toward controlled reactors.
In the books and Amazon adaptation of “The Expanse”, the Epstein Drive as not invented until after Mars had been colonized.
AI, materials science + robotics may get us to an operational fusion power plant before then, but I suspect we’re still 50 – 100 years to go before that happens. If I live to see it happen, it would be very cool indeed.
“…fusion supplying the world with limitless electricity…
…
The most celebrated event in the revival of fusion research came at the Geneva Superpower Summit in November 1985, when General Secretary Mikhail Gorbachev proposed a collaborative international project to develop fusion energy for peaceful purposes.”
The communist dream of limitless abundance of everything seem to never die. It is not a mere coincidence that Soviets promised communism in 20 years. They really thought in 1960s that they were this close to commercial fusion in 1980s. Since then it has become a farce.
I’d rather we just leap ahead to matter – antimatter reactors.
We have ridiculed the Chinese for their high speed rail project (superconducting magnetics) and EVs (lithium batteries and rare earths used in motors and magnets, etc.) and cheap solar panels (thin film processing).
Now it becomes clear the real reason the Chinese have gone that way. They used those projects to develop technologies and supply chains they identified a long time ago as needed for practical fusion.
We need to stop with our quarterly profits and 1 to 5 year business planning and start scoping out the long term projects.
Oh. wait. Scoping out long term climate change solutions…. I have to wonder if that also is part of the Chinese business plan: eliminate the competition.
Hmmm….. Art of War.
Fusion is not practical and may never be. Chinese just produce what seem to work and is profitable now. They leverage economy of scale of internal market to lower the cost, helping to export cheap solar and EVs.
‘They leverage economy of scale…’
They leverage cheap labor, lax environmental restrictions, stolen intellectual property, etc.
The labor isn’t just cheap, its almost free from the slaves in their concentration camps.
And coal fired power plants. Lots of coal fired power plants.
There is no need of any climate change solutions as there is no climate emergency. Stop buying from china and they will be gone. If the US quits buying from china the Chinese economy will quickly collapse.
Reread my post. I thought it was clear my meaning was all of this climate nonsense possibly was part of the Chinese long term planning to take over the world.
We buy from other places because it’s cheaper.
You can only “eliminate the competition” if there is an actual “solution” to an actual (as opposed to imaginary) “problem.”
In this case, it’s more like “encourage the suckers to continue making colossal mistakes.”
Your interpretation is spot on.
French physics Nobel laureate de Gennes said of fusion,
”The idea is pretty. We just put the Sun in a box. The problem is, we don’t know how to make the box.”
Let China try to overcome the problem. Doubt they will.
My bet is on some fourth generation fission concept. Covered in essay ‘Going Nuclear’ in ebook Blowing Smoke
But do we really know how the Sun works? Is it really a self contained plasma ball with a nuclear reaction in the centre? And how does a plasma contain itself? Gravity?
Yes, we do. And the plasma is contained by gravity.
The sun is a simple ‘low mass’ main sequence star. Its end fate is a white dwarf.
Preceded by a red giant. It also locally loses ‘containment’ from time-to-time.
Yes, basic science and astronomy data confirm that about 99% of Sun’s power output is derived from nuclear fusion reactions occurring within the “core” of the Sun, considered to extend from the center to about 0.2 of the solar radius and comprising about 34% of the Sun’s total mass.
— https://en.wikipedia.org/wiki/Solar_core
Gravity, temperature and self-generated magnetic fields confine the extent of the plasma created by nuclear fusion reactions occurring in the Sun.
Can a tokamak ever be large enough to work? Watching the progression over the last 40 years leads me to believe that tokamaks get closer to working as they scale up. It may take something 10 to 100 times the size of ITER to get there.
Stelerators seem to bypass the problem by twisting the plasma in and out instead of confining the plasma with a large toroidal current. There are several proposals on the table promising quick results in much smaller machines. We shall see.
But my bottom line is why not do what we know works, something we have 80 years of experience with already, fission?
I seriously doubt that I have enough time left alive on earth that I will see.
From a practical standpoint, that means I will have to stay warm and dry in my remaining time using other methods.
No one alive today, nor their twenty-fifth generation descendants will ever see commercially-viable fusion power.
Daedalus, using bird feathers, thread, and beeswax, made wings for he and son Icarus to escape imprisonment. Icarus flew too high and sun light melted the wax. Oops!
Sometime later – December 17, 1903, Orville and Wilbur, got their Wright Flyer to cover 120 feet in 12 seconds.
Likely it will take about as long for fusion to achieve a similar breakthrough.
I won’t be here.
I would invite you — [ everyone, especially for your engineering students out there ] — first take a moment to R-E-A-D that (brief) June-2024 Announcement (the link to DOE Fusion Energy Strategy 2024) before falling for all this other promotional hype:
The NIF has since broken their own record, most recently on 23-February-2025; illustrated for novices here:
asks the narrator (Sabine Hossenfelder).
The speaker does not know the practical. So only 15% of the laser is needed to ignite the fuel. That does not increase the efficiency. All of the power for everything is the basis for comparison.
Thanks Sparta Nova 4, but please try again:
What she’s pointing out is that the actual gain on laser-energy delivered (on-target) is 17-fold (rather than 2.5X), because ~ 85% is off-target.
Using the analogy to the Wright-Bros. test-flights, that’s like getting ~ 12 minutes from a test-flight, using a primitive ICE, and knowing that an optimized engine (5X more efficient use of fuel) would turn that into an hour’s flight.
In order to have a practical energy generating system, the output energy must exceed the input energy. The power to the laser is only part of the total input power.
What DOE ‘overlooks’ in its search for continued funding is that the NIF takes at least 4 hours to cool down for the next shot, so can NEVER be a road to commercial electricity.
Seriously? What DoE doesn’t overlook is that they are using 40-year-old laser technology to produce those shots. Literally — flash-lamp pumping instead of diode-lasers.
Reads like an argument against commercial or even military aviation, on the basis that the Wright Brothers had to take 4-hours to refuel between their test-flights. A short decade later … the fighter planes of the First World War.
the flash lamps are used in amplifiers to increase the seed diode laser generated beam energy
The problem with that experiment is that it did not include the energy required to power the laser The 2.05 MJ input was to the fusion fuel,,not the laser input.
Yes, but there’s no deception there: it is a clearly stated deficiency in the (primitive) laser systems used in the Shiva / Nova construction. In other words, your objection is the same as Rud Istvan’s, in a different guise. ( The cool-down time is required to remove all the waste heat in pumping the lasers. It has nothing to do with the fusion-ignition process or its calculation of gain. )
I celebrate the experimental success. Do not doubt that.
However, addressing it as a system, one has to account for all required input energy for comparison to generated output energy.
Gas, coal, wood and nuclear fission all use the same technology to create power, specifically acting as heat sources to produce steam that turns turbines to produce electricity.
Assuming that a sustained fusion reaction was initiated tomorrow, the next task would be to use the energy directly or indirectly to do work to generate electricity. Is there any way that the neutrons from a fission reaction could be used constructively?
You mean like producing plutonium?
“its only byproducts are helium and other greenhouse gases”
He is not a greenhouse gas. It is monatomic. Greenhouse gases are triatomic like H2O and CO2 or pentatomic like methane CH4.
“Ernest Rutherford, who had earlier collaborated with Niels Bohr in the discovery of the neutron”
“In 1932, Rutherford’s theory of neutrons was proved by his associate James Chadwick, who recognised neutrons immediately when they were produced by other scientists and later himself, in bombarding beryllium with alpha particles. In 1935, Chadwick was awarded the Nobel Prize in Physics for this discovery.” https://en.wikipedia.org/wiki/Ernest_Rutherford
I stopped reading there.
I have been reading about controlled fusion reactors since I was a boy 70 years ago. I hope that they really do get one to work before I die. But until I see one that does work, I am from Missouri.
Whether or not fusion is developed in concept is irrelevant to the future supply of electricity. The world has very large supplies of fissile material available over very long time periods, making fusion unnecessary.
Take some of the fusion money and spend it on Thorium Liquid Salts cooled Reactors now – can supply the world for centuries
CANDU reactors demonstrated the ability to use thorium fuel decades ago. The Indian intends to base its future fuel cycle on breeding Th-232 into U-233.
I’m going to go out in a limb here and predict they are not going to overcome this obstacle during my life time. Creating the sun on earth is quite an engineering feet.
And a “feat” as well.
Is anyone following what these guys are doing?
https://www.helionenergy.com/news/
“… many are now saying is far less than “30 years away.”
Again?
Just build coal and gas stations. We have the technology, it’s cheap, safe, clean, quick to build, relatively cheap to run.
A fool’s errand at best, until someone boasts about how many watts was captured from an experiment, Fusion is just a bragging contest of who can achieve the highest temperature (an oven). Physics and 50 years of reading the Fusion headlines suggest that maintaining a sustained fusion reaction is only possible within the gravity well of a star.
Add to that, how many watts were captured versus how many watts expended generating the output.
I know right, I am just waiting for somebody to wrap an induction coil around a reactor somehow and claim 1 was captured.