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agoldis | 7 years ago

Okay, did some search:

- When two hydrogen nuclei combine, they produce an enormous amount of energy. That process is known as nuclear fusion.

- Light nuclei have to be heated to extremely high temperature, it is challenging to create a controlled, safe fusion reactor that offers more energy than it consumes. Once we have such we’d have a near-limitless source of clean energy.

- Nuclear fusion does produce radioactive waste. However, in contrast to fission produced wastes, they are short lived and decay to background levels in a very short time.

- Tokamaks try to do just that.

discuss

i_am_proteus|7 years ago

I will add:

- While the products of the fusion reaction are short-lived, operating a fusion reactor will active materials in the reactor and create some longer-lived radioisotopes.

- Unlike a fission reactor, which is loaded with months to years worth of fuel, a fusion reactor would have fuel constantly injected. So operator action to stop injecting fuel would stop the nuclear reaction.

zrav|7 years ago

There is ongoing research about what to use as chamber wall material. The difficulty is that the material needs to be able to withstand high temperatures, minimize the impurities released when hit by a particles from the fusion plasma and ideally produce short lived and/or harmless isotopes when activated by the fusion radiation. Unfortunately, the metals most used and best known in engineering have the tendency to produce pretty nasty isotopes. The current best candidates are tungsten based alloys.

afraca|7 years ago

Can either you or your parent poster say what "short lived" and "longer-lived" would be roughly?

Aardwolf|7 years ago

> Once we have such we’d have a near-limitless source of clean energy.

In some dystopian future, an AI figures out this is a most efficient use of matter and the entire Earth gets used as fuel for fusion reactions