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The Guardian - AU
The Guardian - AU
National
Donna Lu

Tech coalition aiming to create Australian high-powered laser industry with nuclear fusion ambitions

This undated image provided by the National Ignition Facility at the Lawrence Livermore National Laboratory shows the NIF Target Bay in Livermore, Calif. The system uses 192 laser beams converging at the center of this giant sphere to make a tiny hydrogen fuel pellet implode
A push for Australia to establish a high-intensity laser facility comes as US researchers have made a nuclear fusion reaction breakthrough. Photograph: Damien Jemison/AP

A coalition of technology companies intend to create a high-intensity laser industry in Australia, with potential applications including nuclear fusion.

It follows reports of an expected announcement from the National Ignition Facility at Lawrence Livermore National Laboratory in California that researchers have managed to get more energy out of a nuclear fusion reaction than they put in.

The coalition, led by the Australian laser fusion company HB11 Energy, also includes the University of Adelaide, the Institute of Laser Engineering at Osaka University, the Japanese laser fusion firm EX-Fusion, and the French engineering multinational Thales Group.

It aims to develop an ultra-high intensity laser facility in Australia, with petawatt (one quadrillion, or one million billion watts) lasers.

Dr Warren McKenzie, founder and managing director of HB11 Energy, said Australia was one of few developed countries without such a facility, adding that high-powered lasers could be used for energy generation through nuclear fusion.

“The same lasers can be used, for instance, for the transmutation of fission radioactive waste – essentially reducing the half-life of radioactive waste from hundreds or thousands of years to tens of years,” he said.

McKenzie also described the reported US fusion result as arguably “one of the biggest developments in energy science this century”.

National Ignition Facility researchers have reportedly produced more energy from a nuclear fusion reaction than what was put in – a milestone known as net energy gain.

In a development yet to be confirmed by the NIF, scientists are reported to have shot high-power lasers at a fuel pellet of deuterium and tritium – both isotopes of hydrogen – inside a metal capsule.

“Lasers both heat the fuel … but they also compress it to much higher than its natural density, and the combination of the increase in density from the compression and the heat is what triggers fusion,” McKenzie said.

Prof Ken Baldwin of the Australian National University described the NIF’s apparent advancement as “a truly groundbreaking achievement”, but said it was unlikely fusion power would “save us from climate change”.

“All the heavy lifting for the energy transition will be done by renewable energy and nuclear fission (existing nuclear power) – with nuclear fusion at commercial scale unlikely to be available until later this century, well after the 2050 deadline needed to keep global warming below two degrees. But beyond that, fusion might provide limitless energy for centuries to come,” Baldwin said in a statement.

Mark Diesendorf, an associate professor and deputy director of the Institute of Environmental Studies at the University of New South Wales, agreed that fusion was “decades away from any possibility of commercial electricity generation”.

“There’s a huge gap between this experiment – which I really would hesitate to call a breakthrough – and what has to be done to get commercial electricity out,” he said.

“There’s an intense pulse of laser radiation for a tiny fraction of a second. Then the question is: during that tiny fraction of second, did they get more fusion energy out than they put in?” Diesendorf said. “To generate electricity, what you’ve got to do is to have thousands and thousands … perhaps millions of these pulses a day successfully getting more energy out. And then you’ve got to capture that energy.”

Diesendorf also warned of the risk of nuclear proliferation, pointing out that the Lawrence Livermore National Laboratory, where the fusion breakthrough was made, is a nuclear weapons research facility.

“Fusion produces neutrons and neutrons can be used to transmute elements – so you can get nuclear explosives such as plutonium-239 and uranium-233 and uranium-235,” Diesendorf said. “You can also produce lots of tritium … an essential component of nuclear bombs in missiles.”

McKenzie said HB11 was the first modern private fusion company to demonstrate fusion involving lasers, and that unlike the NIF, it was not using tritium as fuel, but boron. “When we produce fusion, it doesn’t create any radiation or radioactive waste,” he said.

HB11 is still “four orders of magnitude” away from achieving net energy gain. McKenzie said the firm was able to generate 0.01% of the energy input in its fusion reactions.

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