Latest news with #AstralSystems
Times
3 days ago
- Science
- Times
The British mini nuclear fusion reactor that actually works
There are a few things that mark this nuclear fusion reactor out as unusual. For one, it is rather small: it could fit on a table top. For another, this research model currently has a little more gaffer tape than you might expect of the energy technology of the future. But the biggest difference between it and its competitors is that this nuclear fusion reactor, in a warehouse north of Bristol, is actually working. And it is on the cusp of doing something more unusual still: making money. For those who think they may have missed the development of a panacea for the world's energy problems, though, this isn't that — yet. Rather than being a solution for clean electricity the plan is simply to cure cancer by alleviating a desperate shortage of medical radioisotopes. 'We have got thousands of drugs going through medical trials that use nuclear medicine, and at the same time you have got the supply dwindling,' said Dr Tom Wallace-Smith from Astral Systems. Radioisotopes are chemicals that can be used to diagnose or treat cancers. Some, such as iodine-131, are crucial in treatment. But many of the most important ones are made by bombarding other chemicals with neutrons. Currently, doing so relies on ageing nuclear reactors, some of which regularly break down, and none of which are in the UK. Doctors are increasingly concerned about shortages. 'There's this real mismatch, which is constraining the industry,' said Wallace-Smith. This is where he thinks they can help, using nuclear fusion as a new way to provide the necessary neutrons. Nuclear fusion harnesses the processes found in the sun to join together two hydrogen atoms to become one helium and a neutron. The neutrons can then in theory be used to generate electricity. For clean power advocates, if we could get it to work it would be a solution to climate change, providing unlimited carbon-free energy. But to achieve it requires controlling conditions similar to the sun, while also getting more energy out than you put in. Companies and governments around the world have been working for decades to make a practical reactor. At Astral Systems, the company co-founded by Wallace-Smith, who did his PhD at Bristol, they have just such a practical reactor. Or, in fact, several. But the difference is that they aren't looking to get more energy out than in. They are simply looking to make the neutrons, in a device that can sit on a table. 'We don't have enough neutron sources in the UK to make what we need for medicine,' said Simon Middleburgh from Bangor University, which has one of the devices on order. 'The long and the short of it is, this is a compact neutron source.' He said Astral was one of the 'most exciting British nuclear companies to emerge in 20 to 30 years.' As well as making the radioisotopes currently used in medicine, he said that having a small source that could be used in a hospital would open up new isotopes, that currently degrade too rapidly to be transported. 'It opens up a swathe of new isotopes that could be used to treat people and to diagnose people that we don't have available to us at the moment.' But how? Most fusion reactor designs work by containing a plasma in a magnetic field then heating it up to extremely high temperatures. Astral's is different. It uses high voltages to fuse hydrogen together in plasma around a cathode, which then as a consequence starts emitting small quantities of neutrons. 'It's like a neutron light bulb,' said Wallace-Smith. The physics of this has long been well understood. Wallace-Smith's metaphorical light bulb moment came when he helped show that hydrogen isotopes were also bumping into the walls of the device, and more reactions could then occur there, raising the efficiency several times over. 'This meant the plasma is less a light bulb than a spark plug,' he said. It also meant they could get more neutrons out. For now, they are well short of getting more energy out than they put in, although Wallace-Smith doesn't preclude getting there one day. Simply by making money, though, he has done something that very few have achieved, in the 60 years we have been seeking fusion. 'We have shown you can do fusion now, and there's real-world immediate applications,' he said. 'That's the surprise.'
Yahoo
08-06-2025
- Business
- Yahoo
UK firm achieves tritium breakthrough, could boost nuclear fusion fuel supply
Astral Systems, a UK-based private commercial fusion company, has claimed to have become the first firm to successfully breed tritium, a vital fusion fuel, using its own operational fusion reactor. This achievement, made with the University of Bristol, addresses a significant hurdle in the development of fusion energy. The milestone came during a 55-hour Deuterium-Deuterium (DD) fusion irradiation campaign conducted in March. Scientists from Astral Systems and the University of Bristol produced and detected tritium in real-time from an experimental lithium breeder blanket within Astral's multi-state fusion reactors. "There's a global race to find new ways to develop more tritium than what exists in today's world – a huge barrier is bringing fusion energy to reality," said Talmon Firestone, CEO and co-founder of Astral Systems. "This collaboration with the University of Bristol marks a leap forward in the search for viable, greater-than-replacement tritium breeding technologies. Using our multi-state fusion technology, we are the first private fusion company to use our reactors as a neutron source to produce fusion fuel." Astral Systems' approach uses its Multi-State Fusion (MSF) technology. The company states this will commercialize fusion power with better performance, efficiency, and lower costs than traditional reactors. Their reactor design, the result of 25 years of engineering and over 15 years of runtime, incorporates recent understandings of stellar physics. A core innovation is lattice confinement fusion (LCF), a concept first discovered by NASA in 2020. This allows Astral's reactor to achieve solid-state fuel densities 400 million times higher than those in plasma. The company's reactors are designed to induce two distinct fusion reactions simultaneously from a single power input, with fusion occurring in both plasma and a solid-state lattice. The reactor core also features an electron-screened environment. This design reduces the energy needed to overcome the Coulomb barrier between particles, which lowers required fusion temperatures by several million degrees and allows for higher performance in a compact size. The ability to generate tritium within the reactor is crucial. A sustainable fusion energy system needs to produce more fuel than it consumes. This development shows a path toward solving that engineering challenge. In this regard, the latest breakthrough has broad and major implications for several industries, including nuclear fusion energy. 'As we progress the fusion rate of our technology, aiming to exceed 10 trillion DT fusions per second per system, we unlock a wide range of applications and capabilities, such as large-scale medical isotope production, fusion neutron materials damage testing, transmutation of existing nuclear waste stores, space applications, hybrid fusion-fission power systems, and beyond,' remarked the company. Professor Tom Scott, who led the University of Bristol's team, supported by the Royal Academy of Engineering and UK Atomic Energy Authority, concluded, "We're now pushing to quickly optimise our system to further enhance our tritium breeding capability." 'This landmark moment clearly demonstrates a potential path to scalable tritium production in the future and the capability of Multi-State Fusion to produce isotopes in general.'
