How do we prevent the fusion reactor chamber from melting?

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In fusion reactors, high-temperature plasma is contained using strong magnetic fields to prevent contact with the chamber walls, which would otherwise melt. The most advanced project utilizing this method is ITER, a tokamak reactor. While there are alternative approaches to magnetic confinement, such as stellarators like Wendelstein 7-X, these still rely entirely on magnetic fields. Tokamaks generate magnetic fields from plasma currents in addition to external coils, whereas stellarators use coils exclusively. Understanding these methods is crucial for advancing fusion technology.
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this question might be a bit stupid, but if the plasma in the fusion reactor has very high temperature, then how do we make the chamber not melt? i mean, not to join? contact? each other(chamber wall and plasma).
do we use magnetic field to make the distance? then how do we do that?
 
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rootone said:
There is at least one other approach which is not entirely reliant on magnetic confinement, although that is still a part of the story.
https://en.wikipedia.org/wiki/Wendelstein_7-X

This statement is very misleading. It is true that there are alternatives to magnetic confinement.
However, stellarators like Wendelstein rely entirely of magnetic confinement.
 
thanks!
 
OK thanks for that correction, I had thought that the stellarator project used a combination of containment methods, with magnetism being one, but didn't have time to recheck on that.
 
Both tokamak and stellarator use magnetic fields only. Just the origin of the field is different: Tokamaks need a magnetic field component that has to come from a plasma current (together with the stronger fields from coils), stellarators work with magnetic fields from coils only.
 

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