几乎取之不尽的能源 - ITER 聚变等离子体将在真空中悬浮

几乎取之不尽的能源 - ITER 聚变等离子体将在真空中悬浮

ITER 聚变反应堆有望在 2035 年在地球上制造出“人造太阳”。它可以通过聚合氢原子核开发用之不竭的能源。真空是触发和控制核聚变不可或缺的条件。
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When hydrogen atoms are converted into Helium, vast amounts of energy are released. This process does not produce greenhouse gases or endlessly radioactive waste. Neutron bombardment only produces minimal radioactivity in certain metal components of the system, which can be easily controlled by technical means.

A solution to one of humanity's problems?

Successfully harnessing this energy source could solve some of humanity's most pressing problems in one fell swoop – and much of humanity is playing a part in this project: the EU and Switzerland, the USA, China, South Korea, Japan, Russia, and India have come together in a rarely seen globally cooperative effort. It was initiated by Presidents Mikhail Gorbachev and Ronald Reagan in an era that now seems distant. Cadarache in southern France was selected as the location for ITER (which means "the way" in Latin).

Fusion fuels the sun. On Earth, this reaction takes place at temperatures even hotter than that of the core of our central star: 15 million degrees Celsius. No earthly material would withstand these temperatures, which is why the fusion material – a hydrogen-helium plasma – is suspended by an extremely strong magnetic field. The reaction takes place in a vacuum chamber. Upon its completion, it will be the largest in the world. It consists of nine 500-ton segments.

Testing for leaks in the chamber segments

Before they are assembled, they will be checked for leaks. This also takes place under vacuum. Busch supplied two powerful vacuum pumps for tests to ITER. In the future, a large number of powerful vacuum generators will be required to evacuate the entire vacuum chamber. The reactor is expected to be completed in 2025, after which the test runs will begin. Plans are to begin running the self-sustaining fusion reaction in 2035.

The extremely powerful magnetic field that will suspend the hot plasma will be generated by superconducting coils. They need to be cooled to a few degrees above absolute zero. To maintain this other extreme temperature, they are contained within a cryostat – an insulated vacuum chamber with a diameter of 29 meters.

When two atomic nuclei are fused together, enormous amounts of energy are released. This is because the mass of the initial nuclei is larger than the mass of the nuclei created, including the neutrons that are released. Thanks to Einstein – E=mc2 – we know that energy and mass are actually the same. The reduction in mass occurring by the fusion reaction corresponds to the released energy.

On Earth, these reactions are best achieved using the hydrogen isotopes deuterium and tritium. When they fuse, a helium nucleus is created and a neutron is released. One single gram of fuel could provide 90,000 kilowatt hours of energy. That is equivalent to the energy content of eleven tons of coal. There is a nearly limitless supply of deuterium in seawater. Tritium can be produced from lithium, which is also found in abundance.


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