Source: International Atomic Energy Agency – IAEA
The experiments detailed in the paper were carried out at Lawrence Livermore’s National Laboratory (LLNL). For the last six decades, this laboratory, home to the world’s most powerful laser, has worked to achieve the challenging goal of fusion ignition – producing more fusion energy than the amount of laser energy delivered to the target source. The lab’s ‘National Ignition Facility’ (NIF) uses a method called inertial confinement fusion, which involves smashing a fuel pellet with lasers, as opposed to magnetic confinement fusion, which uses powerful magnets to trap a cloud of atoms, called plasma, in a reactor.
“For over a year and a half after the initial experimental success, […] polar direct drive was the most efficient way to convert laser energy input into fusion output,” Yeamans said.
Heather Whitley, associate programme director for High Energy Density Science at LLNL, developed the initial design for a large diameter polar direct drive (PDD) capsule with Steve Craxton and Emma Garcia of the University of Rochester. She said: “The polar direct drive configuration provides excellent diagnostic access for other high temperature plasma physics experiments.”
Following the PDD experiment, in December 2022 NIF conducted the first controlled fusion experiment to produce a net energy gain with the indirect drive method, a major scientific breakthrough which attracted global attention.
Yeaman’s co-authors are Elijah Kemp, Zach Walters, Heather Whitley and Brent Blue from the Lawrence Livermore Nuclear Laboratory, and Steve Craxton, Patrick McKenty, Emma Garcia and Yujia Yang from the Laboratory for Laser Energetics at the University of Rochester.
The prize ceremony for the 2024 award and the upcoming 2025 award will take place in October during the IAEA Fusion Energy Conference in Chengdu China.
Find out more about the Nuclear Fusion journal, and how to prepare and submit an article here.