Fusion power may run out of fuel before it even gets started

In 2020, Canadian Nuclear Laboratories delivered five steel drums, lined with cork to absorb shocks, to the Joint European Torus (JET), a large fusion reactor in the United Kingdom. Inside each drum was a steel cylinder the size of a…

In 2020, Canadian Nuclear Laboratories delivered five steel drums, lined with cork to absorb shocks, to the Joint European Torus (JET), a large fusion reactor in the United Kingdom. Inside each drum was a steel cylinder the size of a Coke can, holding a wisp of hydrogen gas—just 10 grams of it, or the weight of a couple sheets of paper.

This wasn’t ordinary hydrogen but its rare radioactive isotope tritium, in which two neutrons and a proton cling together in the nucleus. At $30,000 per gram, it’s almost as precious as a diamond, but for fusion researchers the price is worth paying. When tritium is combined at high temperatures with its sibling deuterium, the two gases can burn like the Sun. The reaction could provide abundant clean energy—just as soon as fusion scientists figure out how to efficiently spark it.

Last year, the Canadian tritium fueled an experiment at JET showing fusion research is approaching an important threshold: producing more energy than goes into the reactions. By getting to one-third of this breakeven point, JET offered reassurance that ITER, a similar reactor twice the size of JET under construction in France, will bust past breakeven when it begins deuterium and tritium (D-T) burns sometime next decade. “What we found matches predictions,” says Fernanda Rimini, JET’s plasma operations expert.

But that achievement could be a Pyrrhic victory, fusion scientists are realizing. ITER is expected to consume most of the world’s tritium, leaving little for reactors that come after.

Fusion advocates often boast that the fuel for their reactors will be cheap and plentiful. That is certainly true for deuterium: Roughly one in every 5000 hydrogen atoms in the oceans is deuterium, and it sells for about $13 per gram. But tritium, with a half-life of 12.3 years, exists naturally only in trace amounts in the upper atmosphere, the product of cosmic ray bombardment. Nuclear reactors also produce tiny amounts, but few harvest it.

Most fusion scientists shrug off the problem, arguing that future reactors can breed the tritium they need. The high-energy neutrons released in fusion reactions can split lithium into helium and tritium if the reactor wall is lined with the metal. Despite demand for it in electric car batteries, lithium is relatively plentiful.

But there’s a catch: In order to breed tritium you need a working fusion reactor, and there may not be enough tritium to jump-start the first generation of power plants. The world’s only commercial sources are the 19 Canada Deuterium Uranium (CANDU) nuclear reactors, which each produce about 0.5 kilograms a year as a waste product, and half are due to retire this decade. The available tritium stockpile—thought to be about 25 kilograms today—will peak before the end of the decade and begin a steady decline as it is sold off and decays, according to projections in ITER’s 2018 research plan.

The dwindling tritium supply
The few kilograms of commercially available tritium come from CANDU plants, a type of nuclear reactor in Canada and South Korea. According to ITER projections, supplies will peak this decade, then begin a steady decline that will accelerate when ITER begins burning tritium.

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Even without ITER,supplies woulddecline because ofCANDU retirement,tritium decay, andother sales.
Decline acceleratesas ITER burns 0.9 kgof tritium per year.
Inventory boosted asdecommissioned ITER returns unused tritium.
GRAPHIC: K. FRANKLIN/SCIENCE; (DATA) ITER RESEARCH PLAN WITHIN THE STAGED APPROACH, ITR-18-003, (2018)
ITER’s first experiments will use hydrogen and deuterium and produce no net energy. But once it begins energy-producing D-T shots, Alberto Loarte, head of ITER’s science division, expects the reactor to eat up to 1 kilogram of tritium annually. “It will consume a significant amount of what is available,” he says. Fusion scientists wishing to fire up reactors after that may find that ITER already drank their milkshake.

To compound the problem, some believe tritium breeding—which has never been tested in a fusion reactor—may not be up to the task. In a recent simulation, nuclear engineer Mohamed Abdou of the University of California, Los Angeles, and his colleagues found that in a best-case scenario, a power-producing reactor could only produce slightly more tritium than it needs to fuel itself. Tritium leakages or prolonged maintenance shutdowns will eat away at that narrow margin.

Scarce tritium is not the only challenge fusion faces; the field must also learn to deal with fitful operations, turbulent bursts of plasma, and neutron damage (see sidebar, below). But for Daniel Jassby, a plasma physicist retired from Princeton Plasma Physics Laboratory (PPPL) and a known critic of D-T fusion energy, the tritium issue looms large. It could be fatal for the entire enterprise, he says. “This makes deuterium-tritium fusion reactors impossible.”

IF NOT FOR CANDU reactors, D-T fusion would be an unattainable dream. “The luckiest thing to happen for fusion in the world is that CANDU reactors produce tritium as a byproduct,” Abdou says. Many nuclear reactors use ordinary water to cool the core and “moderate” the chain reaction, slowing neutrons so they are more likely to trigger fission. CANDU reactors use heavy water, in which deuterium takes the place of hydrogen, because it absorbs fewer neutrons, leaving more for fission. But occasionally, a deuterium nucleus does capture a neutron and is transformed into tritium.

If too much tritium builds up in the heavy water it can be a radiation hazard, so every so often operators send their heavy water to the utility company Ontario Power Generation (OPG) to be “detritiated.” OPG filters out the tritium and sells off about 100 grams of it a year, mostly as a medical radioisotope and for glow-in-the-dark watch dials and emergency signage. “It’s a really nice waste-to-product story,” says Ian Castillo of Canadian Nuclear Laboratories, which acts as OPG’s distributor.

Fusion reactors will add significantly to the demand. OPG Vice President Jason Van Wart expects to be shipping up to 2 kilograms annually beginning in the 2030s, when ITER and other fusion startups plan to begin burning tritium. “Our position is to extract all we can,” he says.

But the supply will decline as the CANDUs, many of them 50 years old or more, are retired. Researchers realized more than 20 years ago that fusion’s “tritium window” would eventually slam shut, and things have only got worse since then. ITER was originally meant to fire up in the early 2010s and burn D-T that same decade. But ITER’s start has been pushed back to 2025 and could slip again because of the pandemic and safety checks demanded by French nuclear regulators. ITER won’t burn D-T until 2035 at the earliest, when the tritium supply will have shriveled.

Once ITER finishes work in the 2050s, 5 kilograms or less of tritium will remain, according to the ITER projections. In a worst-case scenario, “it would appear that there is insufficient tritium to satisfy the fusion demand after ITER,” concedes Gianfranco Federici, head of fusion technology at the EuroFusion research agency.

A segment of a huge donut-shaped reactor vessel, suspended in a circular room.
In May, engineers began to assemble ITER’s reactor vessel. The first tritium burns are scheduled for 2035.© ITER ORGANIZATION
Some private companies are designing smaller fusion reactors that would be cheaper to build and—initially at least—use less tritium. Commonwealth Fusion Systems, a startup in Massachusetts, says it has already secured tritium supplies for its compact prototype and early demonstration reactors, which are expected to need less than 1 kilogram of the isotope during development.

But larger, publicly funded test reactors planned by China, South Korea, and the United States could need several kilograms each. Even more will be needed to start up EuroFusion’s planned successor to ITER, a monster of a machine called DEMO. Meant to be a working power plant, it is expected to be up to 50% larger than ITER, supplying 500 megawatts of electricity to the grid.

Fusion reactors generally need a large startup tritium supply because the right conditions for fusion only occur in the hottest part of the plasma of ionized gases. That means very little of the tritium in the doughnut-shaped reactor vessel, or tokamak, gets burned. Researchers expect ITER to burn less than 1% of the injected tritium; the rest will diffuse out to the edge of the tokamak and be swept into a recycling system, which removes helium and other impurities from the exhaust gas, leaving a mix of D-T. The isotopes are then separated and fed back into the reactor. This can take anywhere from hours to days.

DEMO’s designers are working on ways to reduce its startup needs. “We need to have a low tritium [starting] inventory,” says Christian Day of the Karlsruhe Institute of Technology, project leader in the design of DEMO’s fuel cycle. “If you need 20 kilograms to fill it, that’s a problem.”

One way to tame the demand is to fire frozen fuel pellets deeper into the reactor’s burning zone, where they will burn more efficiently. Another is to cut recycling time to just 20 minutes, by using metal foils as filters to strip out impurities quickly, and also by feeding the hydrogen isotopes straight back into the machine without separating them. It may not be a perfect 50-50 D-T mix, but for a working reactor it will be close enough, Day says.

Europe’s future giantThe European Union is planning DEMO, a fusion reactor bigger than ITER that will demonstrate electricity generation from the 2050s.
Forging fusion’s fuel
The hydrogen isotopes deuterium and tritium are essential fuels for fusion. Whereas deuterium is plentiful, tritium is not. Fusion reactors will need lithium walls to breed their own tritium. When struck by neutrons from fusion reactions, lithium splits into tritium and helium. But the production is meager; every available centimeter of the interior must be devoted to breeding.
A slice of DEMOAlthough designs for DEMO are not set, it will need tritium breeding blankets that could use solid or liquid lithium.
A wet blanketBlankets rely onneutron multiplierssuch as lead orberyllium (Be),which boost tritiumproduction by spittingout two neutrons forevery one absorbed.In a liquid blanket, amolten lead-lithium(PbLi) mix circulateswhile pressurizedwater flows pastas coolant.
A bed of pebblesIn a solid lithium system, layers of lithium ceramic pebbles are interleaved with pebbles of beryllium while pressurized helium gas filters throughas a coolant.
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Tritium alternativesAmong fusion fuels, deuterium and tritium burn most easily, but others can work at higher temperatures. The alternatives have the advantage of producing few damaging neutrons or none at all. Also, because their reaction products—protons and helium nuclei—are charged, their energy can directly drive an electric current. In tritium systems, neutrons’ heat must be captured to make steam and drive a turbine.
D-TDeuterium and tritium fuse at 150 milliondegrees, a temperature within many fusion reactors’ reach.
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C. BICKEL/SCIENCE
But Abdou says DEMO’s appetite is still likely to be large. He and his colleagues modeled the D-T fuel cycle for power-producing reactors, including DEMO and its successors. They estimated factors, including the efficiency of burning D-T fuel, the time it takes to recycle unburnt fuel, and the fraction of time the reactor will operate. In a paper published in 2021 in Nuclear Fusion, the team concludes that DEMO alone will require between 5 kilograms and 14 kilograms of tritium to begin—more than is likely to be available when the reactor is expected to fire up in the 2050s.

EVEN IF THE DEMO team and other post-ITER reactor designers can cut their tritium needs, fusion will have no future if tritium breeding doesn’t work. According to Abdou, a commercial fusion plant producing 3 gigawatts of electricity will burn 167 kilograms of tritium per year—the output of hundreds of CANDU reactors.

The challenge for breeding is that fusion doesn’t produce enough neutrons, unlike fission, where the chain reaction releases an exponentially growing number. With fusion, each D-T reaction only produces a single neutron, which can breed a single tritium nucleus. Because breeding systems can’t catch all these neutrons, they need help from a neutron multiplier, a material that, when struck by a neutron, gives out two in return. Engineers plan to mix lithium with multiplier materials such as beryllium or lead in blankets that line the walls of the reactors.

ITER will be the first fusion reactor to experiment with breeding blankets. Tests will include liquid blankets (molten mixtures of lithium and lead) as well as solid “pebble beds” (ceramic balls containing lithium mixed with balls of beryllium). Because of cost cuts, ITER’s breeder systems will line just 4 square meters of the 600-square-meter reactor interior. Fusion reactors after ITER will need to cover as much of the surface as they possibly can to have any chance of satisfying their tritium needs.

The tritium can be extracted continuously or during scheduled shutdowns, depending on whether the lithium is in liquid or solid form, but the breeding must be relentless. The breeding blankets also have a second job: absorbing gigawatts of power from the neutrons and turning it into heat. Pipes carrying water or pressurized helium through the hot blankets will pick up the heat and produce steam that drives electricity-producing turbines. “All of this inside the environment of a fusion reactor with its ultrahigh vacuum, neutron bombardment, and high magnetic field,” says Mario Merola, head of engineering design at ITER. “It’s an engineering challenge.”

For Abdou and his colleagues, it is more than a challenge—it may well be an impossibility. Their analysis found that with current technology, largely defined by ITER, breeding blankets could, at best, produce 15% more tritium than a reactor consumes. But the study concluded the figure is more likely to be 5%—a worrisomely small margin.

One critical factor the authors identified is reactor downtime, when tritium breeding stops but the isotope continues to decay. Sustainability can only be guaranteed if the reactor runs more than 50% of the time, a virtual impossibility for an experimental reactor like ITER and difficult for prototypes such as DEMO that require downtime for tweaks to optimize performance. If existing tokamaks are any guide, Abdou says, time between failures is likely to be hours or days, and repairs will take months. He says future reactors could struggle to run more than 5% of the time.

To make breeding sustainable, operators will also need to control tritium leaks. For Jassby, this is the real killer. Tritium is notorious for permeating the metal walls of a reactor and escaping through tiny gaps. Abdou’s analysis assumed a loss rate of 0.1%. “I don’t think that’s realistic,” Jassby says. “Think of all the places tritium has to go” as it moves through the complex reactor and reprocessing system. “You can’t afford to lose any tritium.”

Two private fusion efforts have decided to simply forgo tritium fuel. TAE Technologies, a California startup, plans to use plain hydrogen and boron, whereas Washington state startup Helion will fuse deuterium and helium-3, a rare helium isotope. These reactions require higher temperatures than D-T, but the companies think that’s a price worth paying to avoid tritium hassles. “Our company’s existence owes itself to the fact that tritium is scarce and a nuisance,” says TAE CEO Michl Binderbauer.

The alternative fusion reactions have the added appeal of producing fewer or even no neutrons, which avoids the material damage and radioactivity that the D-T approach threatens. Binderbauer says the absence of neutrons should allow TAE’s reactors—which stabilize spinning rings of plasma with particle beams—to last 40 years. The challenge is temperature: Whereas D-T will fuse at 150 million degrees Celsius, hydrogen and boron require 1 billion degrees.

Helion’s fuel of deuterium and helium-3 burns at just 200 million degrees, achieved using plasma rings similar to TAE’s but compressed with magnetic fields. But helium-3, although stable, is nearly as rare and hard to acquire as tritium. Most commercial sources of it depend on the decay of tritium, typically from military stockpiles. Helion CEO David Kirtley says, however, that by putting extra deuterium in the fuel mix, his team can generate D-D fusion reactions that breed helium-3. “It’s a much lower cost system, easier to fuel, easier to operate,” he says.

Still, advocates of conventional D-T fusion believe tritium supplies could be expanded by building more fission reactors. Militaries around the world use tritium to boost the yield of nuclear weapons, and have built up their own tritium stockpiles using purpose-built or adapted commercial nuclear reactors.

The U.S. Department of Energy (DOE), for example, relies on commercial reactors—Watts Bar Units 1 and 2, operated by the Tennessee Valley Authority—in which lithium control rods have replaced some of the boron ones. The rods are occasionally removed and processed to extract tritium. DOE supplied PPPL with tritium in the 1980s and ’90s when the lab had a D-T burning reactor. But Federici doesn’t think the agency, or militaries around the world, will get into the business of selling the isotope. “Defense stockpiles of tritium are unlikely ever to be shared,” he says.

Perhaps the world could see a renaissance of the CANDU technology. South Korea has four CANDU reactors and a plant for extracting tritium but does not sell it commercially. Romania has two and is working on a tritium facility. China has a couple of CANDUs and India has built a handful of CANDU derivatives. Their tritium production could be turbocharged by adding lithium rods to their cores or doping the heavy water moderator with lithium. But a 2018 paper in Nuclear Fusion by Michael Kovari of the Culham Centre for Fusion Energy and colleagues argues such modifications would likely face regulatory barriers because they could compromise reactor safety and because of the dangers of tritium itself.

Some say fusion reactors could create their own startup tritium by running on deuterium alone. But D-D reactions are wildly inefficient at tokamak temperatures and instead of producing energy would consume huge amounts of electricity. According to Kovari’s study, D-D tritium breeding might cost $2 billion per kilogram produced. All such solutions “pose significant economic and regulatory difficulties,” Kovari says.

Throughout the decades of fusion research, plasma physicists have been single-minded about reaching the breakeven point and producing excess energy. They viewed other issues, such as acquiring enough tritium, just “trivial” engineering, Jassby says. But as reactors approach breakeven, nuclear engineers like Abdou say it’s time to start to worry about engineering details that are far from trivial. “Leaving [them] until later would be hugely mistaken.”

Correction, 24 June, 10:55 a.m.: An earlier version of this story misstated Jason Van Wart’s name.
RELATED STORY
Breakdowns could plague fusion power plants
BY DANIEL CLERY
For decades, achieving controlled fusion was a physics challenge. But now, as the ITER megaproject gears up to demonstrate fusion’s potential as an energy source—and startup companies race to beat it—the practical roadblocks to fusion power plants are coming into focus. One is a looming shortage of tritium fuel. Others could prevent reactors from ever running reliably—a necessity if fusion is to provide a constant “baseload” to complement intermittent solar and wind power.

Some of fusion’s fitfulness is innate to the design of doughnut-shaped tokamak reactors. The magnetic field that confines the ultrahot, energy-producing plasma is generated in part by the charged particles themselves, as they flow around the vessel. That plasma current in turn is induced by pulses of electrical current in a coil of wire in the doughnut’s hole, each lasting a few minutes at most. In between pulses the magnetic field ebbs, interrupting tokamak operations—and power delivery. The repetitive starts and stops of the reactor’s powerful magnetic fields also generate mechanical stresses that could eventually tear the machine apart.

In theory, the beams of particles and microwaves used to heat the plasma can also drive the plasma current. So can a quirk of plasma physics called the bootstrap effect. Near the edge of the plasma, a sharp pressure gradient causes the particles to spiral in such a way that they interfere with each other and push themselves—by their own bootstraps—around the ring.

Using a combination of beams and bootstrap, researchers at ITER think they can get hourlong runs. But the bootstrap effect works best at high pressures and can push the plasma out of control, potentially damaging the reactor, says Alberto Loarte, head of ITER’s science division.

A turbulent outburst of plasma was caught on camera at the Mega Ampere Spherical Tokamak, a small fusion reactor in the United Kingdom.UK ATOMIC ENERGY AUTHORITY
Such outbursts of turbulent plasma are another headache for reactor operators, because they can scour metal off the vessel’s inner wall, not only threatening its integrity, but also poisoning the plasma. At the Joint European Torus (JET), a U.K.-based tokamak with a reactor wall made of beryllium and tungsten, an automated protection system injects gas into the plasma to staunch the bursts—but not always successfully. “You get drops of beryllium everywhere,” says Fernanda Rimini, JET’s plasma operations expert.

ITER operators hope to quell the disruptions by firing frozen deuterium pellets into the plasma and applying an additional magnetic field. Both measures should make the edge of the plasma slightly leaky, so breakouts are small and manageable rather than big and damaging.

The flood of high-energy neutrons produced by fusion reactions pose another threat. The neutrons are a “double-edged sword,” says materials scientist Andy London of the UK Atomic Energy Authority. On the one hand, they dump heat in the reactor wall that ultimately generates electricity, and they can bombard lithium to breed tritium fuel. But they can also penetrate the reactor walls and lodge in surrounding steel structures, knocking atoms out of position and weakening the material. Nuclei in the structures sometimes absorb the neutrons, creating radioactive isotopes that do further damage. For example, neutron bombardment can turn the nickel in many steel alloys into a form that gives off helium, causing the steel to swell perceptibly. “The metal turns into a sponge,” London says.

Finding tougher materials is a challenge, London says, because “we don’t have the luxury of a fusion reactor we can test materials in.” A planned European accelerator facility in Spain, dubbed IFMIF-DONES, is supposed to test fusion materials with the world’s most intense neutron beam. But construction has not started.

Fixing damaged or weakened reactor components will be slow. Because of the hostile radioactive environment, repairs will rely on robots or remote handling arms that can navigate the narrow access ports of a tokamak. Mohamed Abdou, a nuclear engineer at the University of California, Los Angeles, believes future reactors may operate less than 5% of the time.

Compare this, he says, with today’s fission reactors. They can keep running even when individual fuel rods fail. Cranes can swap out fuel rods in just a couple of days. Availability can be as high as 90%. Achieving something similar for fusion will be “very challenging,” Abdou says.