Laser-Boron
Fusion now a
‘Leading Contender’ for Energy
A laser-driven technique for creating fusion that dispenses with the need for radioactive fuel elements and leaves no toxic radioactive waste is now within reach, says a UNSW physicist.
By Wilson da Silva,University of New South Wales
‘Leading Contender’ for Energy
A laser-driven technique for creating fusion that dispenses with the need for radioactive fuel elements and leaves no toxic radioactive waste is now within reach, says a UNSW physicist.
By Wilson da Silva,
December 14, 2017 -- Dramatic
advances in powerful, high-intensity lasers are making it viable for scientists
to pursue what was once thought impossible: creating fusion energy based on
hydrogen-boron reactions. And an Australian physicist is in the lead, armed
with a patented design and working with international collaborators on the
remaining scientific challenges.
In a paper
in the scientific journal Laser and Particle Beams, lead author Heinrich Hora
from UNSW Sydney and international colleagues argue that the path to
hydrogen-boron fusion is now viable, and may be closer to realisation than
other approaches, such as the deuterium-tritium fusion approach being pursued
by US National Ignition Facility (NIF) and the International Thermonuclear
Experimental Reactor under construction in France.
“I think this puts our approach ahead of all
other fusion energy technologies,” said Hora, who predicted in the 1970s that
fusing hydrogen and boron might be possible without the need for thermal
equilibrium.
Rather than heat fuel
to the temperature of the Sun using massive, high-strength magnets to control
superhot plasmas inside a doughnut-shaped toroidal chamber (as in NIF and
ITER), hydrogen-boron fusion is achieved using two powerful lasers in rapid
bursts, which apply precise non-linear forces to compress the nuclei together.
Hydrogen-boron fusion
produces no neutrons and, therefore, no radioactivity in its primary reaction.
And unlike most other sources of power production – like coal, gas and nuclear,
which rely on heating liquids like water to drive turbines – the energy
generated by hydrogen-boron fusion converts directly into electricity.
But the downside has
always been that this needs much higher temperatures and densities – almost 3
billion degrees Celsius, or 200 times hotter than the core of the Sun.
However, dramatic
advances in laser technology are close to making the two-laser approach
feasible, and a spate of recent experiments around the world indicate that an
‘avalanche’ fusion reaction could be triggered in the trillionth-of-a-second
blast from a petawatt-scale laser pulse, whose fleeting bursts pack a
quadrillion watts of power. If scientists could exploit this avalanche, Hora
said, a breakthrough in proton-boron fusion was imminent.
“It is a most
exciting thing to see these reactions confirmed in recent experiments and
simulations,” said Hora, an Emeritus Professor of Theoretical Physics at UNSW.
“Not just because it proves some of my earlier theoretical work, but they have
also measured the laser-initiated chain reaction to create one billion-fold
higher energy output than predicted under thermal equilibrium conditions.”
Together with 10
colleagues in six nations – including from Israel’s Soreq Nuclear Research
Centre and the University of California, Berkeley – Hora describes a roadmap
for the development of hydrogen-boron fusion based on his design, bringing
together recent breakthroughs and detailing what further research is needed to
make the reactor a reality.
An Australian
spin-off company, HB11 Energy, holds the patents for Hora’s process. “If the
next few years of research don’t uncover any major engineering hurdles, we
could have a prototype reactor within a decade,” said Warren McKenzie, managing
director of HB11.
“From an engineering
perspective, our approach will be a much simpler project because the fuels and
waste are safe, the reactor won’t need a heat exchanger and steam turbine
generator, and the lasers we need can be bought off the shelf,” he added.
Other researchers
involved in the study were Shalom Eliezer of Israel’s Soreq Nuclear Research
Centre; Jose M. Martinez-Val from Spain’s Polytechnique University in Madrid;
Noaz Nissim from University of California, Berkeley; Jiaxiang Wang of East
China Normal University; Paraskevas Lalousis of Greece’s Institute of
Electronic Structure and Laser; and George Miley at the University of Illinois,
Urbana.
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