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this post was submitted on 21 Dec 2023
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Most fusion attempts try to keep a continuous reaction ongoing.
Tokamak reactors, like JET or ITER do this through a changing magnetic field, which would allow a reaction to keep going for minutes, the goal is somewhere around 10-30min.
Stellerator reactors try to do the same through a closed loop, basically a Möbius band of plasma encircled by magnets. The stellerator topology of Wendelstein 7-X was used as VFX for the closed time loop in Endgame. This complex topology allows the reaction to continue forever. Wendelstein 7-X has managed to keep its reaction for half an hour already.
The NIF is different. It doesn't try to create a long, ongoing, controlled reaction. It tries to create a nuclear chain reaction for a tiny fraction of a millisecond. Basically a fusion bomb the size of a grain of rice.
The "promise" is that if one were to just repeat this explosion again and again and again, you'd also have something that would almost continually produce energy.
But so far, the NIF has primarily focused on getting as much data as possible about how the first millisecond of a fusion reaction proceeds. The different ways to trigger it, and how it affects the reaction.
The US hasn't done large scale nuclear testing in decades. Almost everything is now happening in simulations. But the first few milliseconds of the ignition are still impossible to accurately model in a computer. To build a more reliable and stronger bomb, one would need to test the initial part of a fusion reaction in the real world repeatedly.
And that's where the NIF comes in.
I have no disagreement with your assertion, aside from the neglected aspect of in terms of energy in Vs energy out; the research is likely to help inform nuclear weapons design, yet if they are able to achieve more energy out than in (3mj out Vs 2mj in (though of course they required 300mj to run the lasers to produce this reaction)) then they are providing important data that may help inform different future designs of power generating fusion reactors, this is something that current other designs don't appear to have achieved afaik.
I doubt they will ever really use this style as a functional form of power generation, but if what they learn from the research allows eventually for a longer functioning fusion reaction that has an overall positive energy output, then it may be rather valuable.
NIF can't really ever reach Q>1. All the statements of having reached that only include the energy that reaches the capsule. The energy the lasers actually use is orders of magnitude larger.
This theoretical Q>1, where the plasma emits more radiation than it receives, have been reached by other reactors before.
But while tokamak or stellerator designs need a 2-3× improvement to produce more energy than the entire system needs, the NIF would need a 100-1000× improvement to reach that point, which is wholly unrealistic with our current understanding of physics.