Published on the 10th July 2014 by ANSTO Staff
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| Australian Plasma Fusion Research Facility director Professor John Howard, right, with Dr Cormac Corr and the facility's new machine, the MagPIE. Photo: Graham Tidy |
The search for star power – fusion – will receive a major boost with the launch of the Australian Plasma Fusion Research Facility (APFRF) at The Australian National University on Thursday.
The facility includes Australia’s largest fusion experiment, the newly upgraded H1, which will now be able to heat fusion experiments to temperatures hotter than the core of the sun.
The facility also includes a new machine, MagPIE, which will accelerate research into extreme materials to be used in future experiments involving even higher temperatures and radiation levels.
Media are invited to attend the launch at this one of a kind facility in Australia, at which there will be the opportunity to see the experiments in action.
The fusion of hydrogen into helium powers the Sun and the stars. If harnessed on Earth, it could provide millions of years of greenhouse gas-free, safe, base-load power.
The H1 experiment uses strong magnetic fields to confine the hot fuel inside a doughnut-shaped vessel. The doughnut design is also the basis for the next-step fusion energy experiment, ITER, which is being built in the south of France by a global consortium of 35 nations.
ITER will have a ten times larger volume than any existing magnetic fusion experiment and is planned to produce 500 megawatts of power, on par with a small power station.
“ITER’s design hinges on experiments being carried out in experiments around the world, such as the Plasma Fusion Research Facility at ANU,” said the Director General of ITER, Osamu Motojima.
“Choice of materials for use in ITER is an active research area, to which MagPIE is already contributing, in collaboration with ANSTO, who part-funded the project,” says Dr Adi Paterson, CEO of ANSTO.
“Power plant fusion plasmas present an extreme materials challenge. This facility helps us to test whether prototype new materials can withstand the heat flux damage inflicted by a fusion plasma,” Dr Paterson said.
At the same event a five-year plan for fusion research was launched laying out pathways to Australian ITER involvement and enhancements to national experimental fusion science capabilities.
The upgrade to H1 was made possible through a Commonwealth investment of $7.9 million from the National Collaborative Research Infrastructure. Scheme (NCRIS) and associated programs.