From University of New South Wales: “Pioneering technology promises unlimited, clean and safe energy”

U NSW bloc

From University of New South Wales

21 Feb 2020
Yolande Hutchinson
UNSW Sydney External Relations
0420 845 023
y.hutchinson@unsw.edu.au

Dr Warren McKenzie
HB11 Energy
0400 059 509

Professor Heinrich Hora
UNSW Physics
0414 471 424

A UNSW spin-out company has secured patents for its ground-breaking approach to energy generation.

1
HB11 Energy, has been granted patents for its laser-driven technique for creating fusion energy. Picture: Shutterstock

UNSW Sydney spin-out company, HB11 Energy, has been granted patents for its laser-driven technique for creating fusion energy. Unlike earlier methods, the technique is completely safe as it does not rely on radioactive fuel and leaves no toxic radioactive waste.

HB11 Energy secured its intellectual property rights in Japan last week, following recent grants in China and the USA.

Conceived by UNSW Emeritus Professor of theoretical physics Heinrich Hora, HB11 Energy’s concept differs radically from other experimental fusion projects.

“After investigating a laser-boron fusion approach for over four decades at UNSW, I am thrilled that this pioneering approach has now received patents in three countries,” Professor Hora said.

“These granted patents represent the eve of HB11 Energy’s seed-stage fundraising campaign that will establish Australia’s first commercial fusion company, and the world’s only approach focused on the safe hydrogen – boron reaction using lasers.”

The preferred fusion approach employed by most fusion groups is to heat Deuterium-Tritium fuel well beyond the temperature of the sun (or almost 15 million degrees Celsius). Rather than heating the fuel, HB11’s hydrogen-boron fusion is achieved using two powerful lasers whose pulses apply precise non-linear forces to compress the nuclei together.

“Tritium is very rare, expensive, radioactive and difficult to store. Fusion reactions employing Deuterium-Tritium also shed harmful neutrons and create radioactive waste which needs to be disposed of safely. I have long favored the combination of cheap and abundant hydrogen H and boron B-11. The fusion of these elements does not primarily produce neutrons and is the ideal fuel combination,” Professor Hora said.

Most other sources of power production, such as coal, gas and nuclear, rely on heating liquids like water to drive turbines. In contrast, the energy generated by hydrogen-boron fusion converts directly into electricity allowing for much smaller and simpler generators.

The two-laser approach needed for HB11 Energy’s hydrogen-boron fusion only became possible recently thanks to advances in laser technology that won the 2018 Nobel Prize in Physics.

2
Schematic of a hydrogen-boron fusion reactor.

Hora’s reactor design is deceptively simple: a largely empty metal sphere, where a modestly sized HB11 fuel pellet is held in the center, with apertures on different sides for the two lasers. One laser establishes the magnetic containment field for the plasma and the second laser triggers the ‘avalanche’ fusion chain reaction.

The alpha particles generated by the reaction would create an electrical flow that can be channeled almost directly into an existing power grid with no need for a heat exchanger or steam turbine generator.

“The clean and absolutely safe reactor can be placed within densely populated areas, with no possibility of a catastrophic meltdown such as that which has been seen with nuclear fission reactors,” Professor Hora added.

With experiments and simulations measuring a laser-initiated chain reaction creating one billion-fold higher reaction rates than predicted (under thermal equilibrium conditions), HB11 Energy stands a high chance of reaching the goal of ‘net-energy gain’ well ahead of other groups.

“HB11 Energy’s approach could be the only way to achieve very low carbon emissions by 2050. As we aren’t trying to heat fuels to impossibly high temperatures, we are sidestepping all of the scientific challenges that have held fusion energy back for more than half a century,” Dr Warren McKenzie, Managing Director of HB11 Energy, said.

“This means our development roadmap will be much faster and cheaper than any other fusion approach,” Dr McKenzie added.

See the full article here .


five-ways-keep-your-child-safe-school-shootings

Please help promote STEM in your local schools.

Stem Education Coalition

U NSW Campus

Welcome to UNSW Australia (The University of New South Wales), one of Australia’s leading research and teaching universities. At UNSW, we take pride in the broad range and high quality of our teaching programs. Our teaching gains strength and currency from our research activities, strong industry links and our international nature; UNSW has a strong regional and global engagement.

In developing new ideas and promoting lasting knowledge we are creating an academic environment where outstanding students and scholars from around the world can be inspired to excel in their programs of study and research. Partnerships with both local and global communities allow UNSW to share knowledge, debate and research outcomes. UNSW’s public events include concert performances, open days and public forums on issues such as the environment, healthcare and global politics. We encourage you to explore the UNSW website so you can find out more about what we do.