Ah, okay, that’s what I was referring to with NIF. They absolutely have generated more power than they put in, but only in a way that is scientifically interesting. If you only consider the energy flowing into the hohlraum, then more energy was produced, which is crazy cool! They also achieved true ignition which is great. We’ve never been able to get things hot enough and squozed enough for long enough to be able to directly observe that in a controlled setting. The fact that they can now just do that means the they can experimentally probe where the boundaries are and find the cheapest way for us to get to ignition.
However, they got the energy to the hohlraum using lasers. Those lasers (and all of the equipment around them) required (I think) three orders of magnitude more power to generate the laser impulse that triggered fusion. A productive fusion reaction did occur, but it absolutely wasn’t productive enough to make up for all the power required to generate the laser pulse. Making lasers that can output at the required power levels and frequencies without all of the waste (i.e. 2.5 MJ of electricity to laser results in 2 MJ laser output) is a Hard Problem™ and is probably impossible with our current understanding of physics.
When you made your comment, I wondered if someone had achieved breakeven using a tokamak or some other form of magnetic confinement setup. Inertial confinement fusion is great for research but not practical for power generation, whereas magnetic confinement fusion is probably where the future is.
ICF is really good at putting the squoze on stuff, because the things you want to fuse are all stuffed in a tiny hohlraum and you’re zorching it with a shitload of giant friggin lasers. Magnetic confinement fusion used in tokamaks occurs much more gradually by magnetically heating and containing plasmas. The nice thing about tokamaks is that they just constantly generate heat. With modern superconducting magnets, the infrastructure efficiency is also pretty decent, giving them a chance at truly generating more power than they use when you take the entire reactor into consideration.
Jesus that’s a lot of words. I should go do my damn job instead of distracting myself talking about fusion. Sorry for the brain dump.
No worries, I didn’t think you were trying to mislead! I’m also very hopeful for fusion and I like to read about it. I don’t know if magnetic confinement systems will be able to reach the temperatures and pressures required for ignition (versus those just for fusion) soon, but technological progress certainly has a tendency towards jumping forwards unexpectedly!
Ah, okay, that’s what I was referring to with NIF. They absolutely have generated more power than they put in, but only in a way that is scientifically interesting. If you only consider the energy flowing into the hohlraum, then more energy was produced, which is crazy cool! They also achieved true ignition which is great. We’ve never been able to get things hot enough and squozed enough for long enough to be able to directly observe that in a controlled setting. The fact that they can now just do that means the they can experimentally probe where the boundaries are and find the cheapest way for us to get to ignition.
However, they got the energy to the hohlraum using lasers. Those lasers (and all of the equipment around them) required (I think) three orders of magnitude more power to generate the laser impulse that triggered fusion. A productive fusion reaction did occur, but it absolutely wasn’t productive enough to make up for all the power required to generate the laser pulse. Making lasers that can output at the required power levels and frequencies without all of the waste (i.e. 2.5 MJ of electricity to laser results in 2 MJ laser output) is a Hard Problem™ and is probably impossible with our current understanding of physics.
When you made your comment, I wondered if someone had achieved breakeven using a tokamak or some other form of magnetic confinement setup. Inertial confinement fusion is great for research but not practical for power generation, whereas magnetic confinement fusion is probably where the future is.
ICF is really good at putting the squoze on stuff, because the things you want to fuse are all stuffed in a tiny hohlraum and you’re zorching it with a shitload of giant friggin lasers. Magnetic confinement fusion used in tokamaks occurs much more gradually by magnetically heating and containing plasmas. The nice thing about tokamaks is that they just constantly generate heat. With modern superconducting magnets, the infrastructure efficiency is also pretty decent, giving them a chance at truly generating more power than they use when you take the entire reactor into consideration.
Jesus that’s a lot of words. I should go do my damn job instead of distracting myself talking about fusion. Sorry for the brain dump.
I apologize— my intent wasn’t to be misleading, just highly optimistic about the future.
No worries, I didn’t think you were trying to mislead! I’m also very hopeful for fusion and I like to read about it. I don’t know if magnetic confinement systems will be able to reach the temperatures and pressures required for ignition (versus those just for fusion) soon, but technological progress certainly has a tendency towards jumping forwards unexpectedly!