The world’s biggest operational experimental nuclear fusion reactor – a technology in its infancy but billed by some as the answer to humanity’s future energy needs – has been inaugurated in Naka, Japan.

Fusion differs from fission, the technique used in nuclear power plants, by fusing two atomic nuclei instead of splitting one.

The goal of the JT-60SA reactor is to investigate the feasibility of fusion as a safe, large-scale and carbon-free source of net energy – with more energy generated than is put into producing it.

The six-storey-high machine, in a hangar in Naka, north of Tokyo, comprises a doughnut-shaped “tokamak” vessel set to contain swirling plasma heated to 200 million degrees celsius.

It is a joint project between the European Union and Japan, and is the forerunner for its big brother in France, the under-construction International Thermonuclear Experimental Reactor (ITER).

The ultimate aim of both projects is to coax hydrogen nuclei inside to fuse into one heavier element, helium, releasing energy in the form of light and heat, and mimicking the process that takes place inside the sun.

Researchers at ITER, which is over budget, behind schedule and facing major technical problems, hope to achieve nuclear fusion technology’s holy grail, net energy.

Sam Davis, the deputy project leader for the JT-60SA, said the device would “bring us closer to fusion energy”.

“It’s the result of a collaboration between more than 500 scientists and engineers and more than 70 companies throughout Europe and Japan,” Davis said at Friday’s inauguration.

The EU energy commissioner, Kadri Simson, said the JT-60SA was “the most advanced tokamak in the world”, and called the start of operations “a milestone for fusion history”.

“Fusion has the potential to become a key component for energy mix in the second half of this century,” Simson added.

The feat of “net energy gain” was managed last December at the National Ignition Facility at Lawrence Livermore National Laboratory in the US, home to the world’s largest laser.

The US facility uses a different method to ITER and the JT-60SA known as inertial confinement fusion, in which high-energy lasers are directed simultaneously into a thimble-sized cylinder containing hydrogen.

The US government called the result a “landmark achievement” in the quest for a source of unlimited, clean power and an end to reliance on carbon-emitting fossil fuels that cause climate change as well as geopolitical upheaval.

Unlike fission, fusion carries no risk of catastrophic nuclear accidents, such as the disaster in Fukushima in Japan in 2011, and produces far less radioactive waste than current power plants, its exponents say.

 This article was amended on 2 December 2023. An earlier version incorrectly gave the estimated upper temperature of the heated plasma as “200mC”. The figure has been amended to 200 million degrees celsius (200MC, or mega-degrees celsius).

Source : The Guardian

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