From: https://www.sciencealert.com/physics
By David Nield
September 9, 2022 -- Korea's 'artificial Sun'
reactor has made headlines this week by officially sustaining plasma
at a temperature of 100 million degrees Celsius for more than 20 seconds.
The team at the Korea
Superconducting Tokamak Advanced Research (KSTAR) device reached an ion
temperature of above 100 million degrees Celsius (180 million degrees
Fahrenheit).
According to New
Scientist, the reaction was only stopped after 30 seconds because of
hardware limitations.
KSTAR uses magnetic
fields to generate and stabilize ultra-hot plasma, with the ultimate aim of
making nuclear fusion power a reality.
You can see the footage
below showing the reactor run over 24 seconds, and achieving a temperature of
more than 10^8 Kelvin – which is more or less equivalent to 100
million degrees Celsius.
One of the KSTAR
researchers, Yong-Su Na, told Matthew Sparkes from New Scientist that
longer periods should be possible in future after upgrades to the device.
This is an exciting
achievement for good reason – a potentially unlimited source of clean energy
that could transform the way we power our lives, if we can get it to work as
intended.
But it's also worth
noting that this advance by KSTAR isn't necessarily a brand new record, as some
media are touting.
In fact, KSTAR
announced this breakthrough back in 2020, and we reported on it at the
time. What's changed now is their paper on the research has been peer-reviewed
and has just been published in Nature.
However, in the years
since, the KSTAR team has broken their own record, and China's 'artificial
Sun' known as EAST (Experimental Advanced Superconducting Tokamak or
HT-7U) has gone on to smash both of those.
In 2021, the Chinese
Academy of Sciences' fusion machine reached 120 million degrees Celsius (216
million degrees Fahrenheit) and clung onto it for 101 seconds.
That's not to say the
KSTAR achievement still isn't huge and worth sharing and celebrating.
Before this
breakthrough, the threshold of 100 million degrees hadn't been breached for
more than 10 seconds.
"The technologies
required for long operations of 100 million-degree plasma are the key to the
realization of fusion energy," said nuclear physicist Si-Woo Yoon, a
director at the KSTAR Research Centre at the Korea Institute of Fusion Energy
(KFE) back in 2020.
"The KSTAR's
success in maintaining the high-temperature plasma for 20 seconds will be an
important turning point in the race for securing the technologies for the long
high-performance plasma operation, a critical component of a commercial nuclear
fusion reactor in the future."
Key to the leap to 20
seconds was an upgrade to the Internal Transport Barrier (ITB) modes inside the
KSTAR. These modes aren't fully understood by scientists, but on the
simplest level they help to control the confinement and the stability of the
nuclear fusion reactions.
The KSTAR is a tokamak-style
reactor, similar to the one that recently went online in China, merging
atomic nuclei to create these huge amounts of energy (as opposed to nuclear
fission used in power plants, which splits atomic nuclei apart).
Fusion devices like
KSTAR use hydrogen isotopes to create a plasma state where ions and electrons
are separated, ready for heating – the same fusion reactions that happen on the
Sun, hence the nickname these reactors have been given.
As yet, maintaining
high-enough temperatures for a long enough period of time for the technology to
be viable has proved to be challenging. Scientists are going to need to break
more records like this for nuclear fusion to work as a power source – running off
little more than seawater (a source of hydrogen isotopes) and producing minimal
waste.
Despite all the work
that lies ahead in getting these reactors to produce more energy than they
consume, progress has been encouraging. By 2025, the engineers at KSTAR
want to have exceeded the 100 million-degree mark for a period of 300 seconds.
"The 100
million-degree ion temperature achieved by enabling efficient core plasma
heating for such a long duration demonstrated the unique capability of the
superconducting KSTAR device, and will be acknowledged as a compelling basis
for high performance, steady state fusion plasmas," said nuclear
physicist Young-Seok Park, from Columbia University, back in 2020.
The research has been
published in Nature.
Parts of this article
were first published in December 2020.
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