Nuclear fusion is a concept in bonding atoms together comes two
steps closer? As the quest to produce a working nuclear fusion reactor has been
the dream of scientists for decades. However, progress has been painfully slow.
Within just a few days though, news of two major breakthroughs in the
technology 2016 it has emerged control of reaction without lag that being decay of elements known as
reactive waste. Is the world ready for nuclear fusion bonding atoms in a chain reaction and can technology make this power a solution to maintain electrical
power for modern transport like taxis.
It is promising then that over the last week, two
experimental results emerged which were hailed as significant milestones for
nuclear fusion technology. On Wednesday, German Chancellor Angela Merkel
pressed a button to initiate a test at the experimental Wendelstein 7-X fusion
reactor in Germany, that successfully managed to produce and contain hydrogen
plasma for a quarter of a second. Then, just five days later, with the
scientific community still digesting the news from Germany, Chinese scientists
at a rival reactor, the Experimental Advanced Superconducting Tokamak (EAST),
made a surprise announcement. They revealed that they had managed to produce
and contain hydrogen plasma for a record 102 seconds, far longer than the
Wendelstein, albeit at a much lower temperature –around 50 million degrees
Celsius, as opposed to 80 million degrees Celsius.
As they note the temperature of the plasma inside the ESTA is
roughly three times hotter than the core of the sun. However, this pales in
comparison to the hottest ever man-made temperature. Temperatures inside the
Large Hadron Collider in Switzerland reached 5.5 trillion degrees Celsius for a
fraction of a second, during an experiment designed to create exotic forms of
matter which only existed in the first few moments after the Big Bang. This
was, as far as we know, the hottest temperature in the universe at that point. 
Meanwhile, the hottest man-made plasma ever created reached 510 degrees Celsius
at the Tokamak Fusion Test Reactor, in Princeton, New Jersey, which operated
between 1982 and 1997. So how does nuclear fusion work and what are the
implications of the experimental results coming from China and Germany? Fusion
reactors work by heating particles to millions of degrees Celsius while
suspending and containing the resulting plasma using incredibly powerful,
super-cooled magnets. In this superheated state, the particles in the atoms
collide with each other and fuse together, resulting in the creation of huge
amounts of energy. This is the same process of energy production which occurs
in the core of stars. The ultimate goal of fusion reactors is to harness the
energy that is produced in this process.
As the concept of producing more
energy than is consumed ‘has been demonstrated, albeit on a very small scale’ In
an experiment carried out at The National Ignition Facility (NIF) in the United
States, where scientists produced as much as 2.6 times more energy than was
present in the fuel. This becomes a relatively
new science duplicating of forms. Once the technology is sufficiently advanced,
scientists hope nuclear fusion could have the potential to provide a near
limitless source of clean energy using virtually inexhaustible raw materials.
This is because any viable reactors will eventually run on deuterium, a stable
isotope of hydrogen which can be easily extracted from seawater.
Nuclear fission works by splitting atomic bonds to produce
energy rather than fusing them together. The two major types of fusion reactors
are called stellarators, like the Wendelstein, and tokamaks like the EAST. They
are designed using the same basic concepts, however there are some differences
in the way they work. Tokamaks, the more traditional design of the two, utilise
a huge network of magnets in a doughnut-shaped ring. They create plasma in
pulses, which means that they have to be turned on and off and refuelled to
produce new plasma picture of the planet Venus.
A stellarator
on the other hand is designed like a twisted tokamak, with each ring that comprises
the structure of the tokamak, contorted in a very precise way according to
complex mathematical calculations. The practical advantage of this is that
while tokamaks can only work in short bursts, a stellarator could, in theory,
run continuously. The interior of the new Wendelstein 7-X nuclear fusion
reactor on February 3, 2016 in Greifswald, Germany - Adam Berry/Getty The
potential of stellarators has been recognised for many years but they are
incredibly difficult to construct in comparison to other types of reactors,
meaning few have ever been completed. Only state-of-the-art computer design
technology has made construction of the Wendelstein possible.
Implications as both the Chinese and German reactors are
proof-of-concepts, so they are not designed to harness any energy they produce,
but their respective breakthroughs are exciting in their own ways, even though
the length of time they can produce plasma appears short. The Wendelstein’s
feat was the first time that a stellarator design was able to successfully
produce and contain hydrogen plasma. Scientists predict that in future
experiments, the reactor will be capable of maintaining plasma at the necessary
heat for fusion, for up to 30 minutes.
Hydrogen plasma had been produced and contained in other
types of reactors before the Wendelstein's experiment. The facility has also
been producing helium plasma in experiments since December, in what is
considered an easier and less useful process. Results from the Chinese reactor,
on the other hand, are promising because they demonstrate that tokamak reactors
can produce and contain hydrogen plasma for a significant amount of time, even
though they are limited to working in bursts. It should be made clear that the
results from China have not yet been peer-reviewed, but the team has already
set a target of heating the hydrogen plasma to 100 million degrees – considered
the ideal temperature for fusion - for 1,000 seconds in future experiments.
The encouraging signs from both stellarator and tokamak
technologies could pave the way for new, more effective kinds of reactors in
the future. Thomas Klinger, director at the Max Planck Institute where the
Wendelstein reactor is based, told phys.org that the two differing designs do not
necesarily need to compete against each other. “It's not a race,” he said. “In
the end they do not represent two different worlds; the two branches of
research provide mutual inspiration for each other. Insights from stellarator
research have been incorporated into the development of the tokamak and vice
versa. They are two pillars of a large edifice. The exact form the edifice will
ultimately take is something we do not yet know. It is even conceivable today
that a fusion power plant will be built one day as a hybrid of the two types.”
It aims to
produce 500 megawatts of power in 400 second bursts while only requiring only
50 megawatts to operate. In other words, it will produce ten times the power
that it requires to run on. ITER was slated to begin operations in 2020,
however, the project has been delayed due to a series of technical problems and
rising costs. If this is achieved and advances are made in other areas, the
next generation of fusion reactors have the potential to revolutionise the
world’s energy supply, however, a working, commercially viable version is still
likely to be a few decades away from completion, as modern maths fills in some
questions still very new technology.
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