European scientists make ‘landmark’ nuclear fusion breakthrough
Experiment at UK’s experimental JET facility boosts hope that clean power source could soon be harnessed commercially
European scientists have generated the biggest amount of energy from fusion in the latest breakthrough in the decades-long effort to generate clean, cheap power by harnessing the reaction that powers the stars.
The UK's Atomic Energy Authority announced on Wednesday that a team of European researchers had produced 59 megajoules from a sustained reaction lasting five seconds — enough power to boil about 60 kettles — in an experiment at the Joint European Torus facility in Oxford, England.
This is more than double what was achieved in similar tests back in 1997, report BBC.
It's not a massive energy output - only enough to boil about 60 kettles' worth of water. But the significance is that it validates design choices that have been made for an even bigger fusion reactor now being constructed in France.
"The JET experiments put us a step closer to fusion power," said Dr Joe Milnes, the head of operations at the reactor lab. "We've demonstrated that we can create a mini star inside of our machine and hold it there for five seconds and get high performance, which really takes us into a new realm."
"These landmark results have taken us a huge step closer to conquering one of the biggest scientific and engineering challenges of them all," said Ian Chapman, chief executive of the UKAEA.
JET, a collaboration between EU member states, Switzerland, the UK and Ukraine, founded in 1978, is the world's largest, most powerful operational "tokamak" machine. The design, pioneered by Soviet scientists in the 1950s, uses powerful magnets to hold a plasma of two hydrogen isotopes — deuterium and tritium — in place as it is heated to temperatures hotter than the sun so that the atomic nuclei fuse, releasing energy.
In half a century of experiments around the world scientists have failed to generate more energy from a fusion reaction than the power-intensive system consumes.
Arthur Turrell, a fusion expert, said the latest breakthrough, which more than doubles the previous energy output record of 22 megajoules, achieved by JET in 1997, was another significant step forward. "In terms of power its equivalent to about four wind turbines, that's close to industrial scale," said Turrell, whose book The Star Builders charts the multi-decade effort to achieve fusion energy.
Unlike nuclear fission when atoms are split, fusion does not produce significant radioactive waste. But the biggest challenge to make fusion commercial is how to sustain the reaction and prevent it from extinguishing.
Sustaining the power output for five seconds was therefore particularly significant, explained Turrell. "That might not sound that impressive but five seconds is an incredibly long time on nuclear timescales," he said. "It suggests that the stability problem is under control which brings them a big step closer to fulfilling the full problem."
Fusion energy has plenty of sceptics given how long it has taken to make any significant breakthrough but its promise as a way to fight climate change has increased interest over the past decade.
Fusion-power would emit no greenhouse gases and supplies of the chemical inputs are essentially inexhaustible. There are approximately 5g of deuterium in every bathtub of seawater and while tritium is less accessible it can be extracted from the commonly occurring metal lithium, or generated in the reaction itself. A small glass of fuel could theoretically power a house for hundreds of years.
While JET is one of several large, publicly funded fusion projects around the world, private sector money has also been flowing into fusion energy start-ups at record levels. Total private sector financing had reached more than $3bn by the end of 2021.
Turrell said the JET breakthrough should be good news for fusion start-ups, some of which are promising to deliver commercial power by the 2030s.
"This shows [private companies] that it is possible to do it and to keep the plasma stable," he added. "With technologies, once you know something is possible, lots of people work out ways to get there."