Laser Fusion Energy: The Future of NIF Lasers

Friday - September 29 2023, 16:01 UTC - 1 year ago

At the 2023 International Conference on Inertial Fusion Sciences and Applications, I have seen leaders of the LLNL NIF team showcase their 3 major results of using lasers to create fusion energy. For a more commercial application of this, LLNL and the National Nuclear Security Administration are planning to increase the power of the NIF system with the hope of achieving 10-20MJ or more in the future. Their success in this venture could result in a future of commercial inertial fusion energy.

I am attending the 2023 International Conference on Inertial Fusion Sciences and Applications where there have been numerous presentations by leaders of the LLNL NIF team. I have also spoken with several of the speakers.

The Big 3 recent results were: .

1. Aug 8, 2021 1.9 megajoules (MJ) of laser power was fired at a target which resulted in the release of 1.35 megajoules (0.72 return) .

2. Dec 5, 2022 2.05 megajoules was fired at a target which resulted in the release of 3.15 megajoules (1.54X gain) .

3. July 30, 2023 2.05 megajoules was fired at a target which resulted in the release of 3.88 megajoules (1.9X gain)After Aug 8, 2021 there were several shots that did not reach a megajoule of returned power. There was a lot of work improving the targets and adjusting how the lasers were fired. The power of the entire system was increased by 8% from 1.9 MJ to 2.05 MJ. The quality of the targets had to be improved. They had to prevent three different major kinds of errors.

Keeping the system working at 2.05MJ or even 1.9MJ is difficult. The system is operating beyond its designed levels of 1.8MJ. The NIF system has damage that has to be repaired after shots are made.

There is software autotuning to calculate the adjustments to the laser pulse the target (holhraum).

There are plans to increase the power to 3 MJ which would conservatively deliver more than a 10X gain and 30 MJ.

They have already prepared the NIF lasers and facility to operate with 2.2 MJ shots. The first 2.2 MJ shot are calculated to deliver 5-10 MJ. Modifying the target shape from a pill capsule like shape to one with a wide centerline with two stacked trapezoids (Frustraum) could deliver over 10 MJ using 2.2 MJ of laser power.

Tests have been made that indicate the current system could reach 2.6 MJ with fresh amplifier glass lens. NIF has bought and stored all of the original production of amplifier glass. The 2.6 MJ (and any midpoint between 2.2 MJ and 3MJ) has not been funded or approved. However, it would offer a lot of fusion bang for the buck to go to 2.6 MJ and then to make the modifications for 3 MJ. Timing and schedules are all highly uncertain but 2 years at 2.2MJ and then 2 years of testing at 2.6MJ makes sense to me. A .

There is still selections and approvals to be made on how to perform higher power or high energy work.

The National Nuclear Security Administration (NNSA) makes the decisions about LLNL operations. Since its inception in 1952, LLNL’s defining responsibility has been national security — ensuring the safety, security and effectiveness of the nation’s nuclear stockpile. Nuclear Stockpile sustainment is still the main role.

LLNL’s mission has broadened in recent years, as dangers ranging from nuclear proliferation and terrorism to cyber-attacks and climate change increasingly threaten national security and global stability.

LLNL developing and proving that laser nuclear fusion is promising for potential commercial energy generation is greatly appreciated.

Future of NIF Laser Fusion .

I think that the campaigns to increase NIF power to 2.6 MJ and to 3 MJ makes a lot of sense. It could also achieve 10-20MJ or more at 2.6MJ and at 3MJ. That would demonstrate conclusively that industrial inertial fusion energy is technically feasible, and directs focus on producing energy for commercial or military use.