MIT Contributes to Success of Historic Fusion Ignition Experiment

Success of Historic Fusion Experiment

MIT has contributed to the success of the ignition program at the National Ignition Facilty for more than a decade by providing and using a dozen diagnostics, implemented by MIT PhD students and staff, which have been critical for assessing the performance of an implosion, like the one pictured. Credit: Image courtesy of Lawrence Livermore National Laboratory.

MIT students are part of the large team that achieved fusion ignition for the first time in a laboratory.

Researchers around the world have been engaged in attempts to achieve fusion ignition in a laboratory for more than half a century. It is a grand challenge of the 21st century. An approach called inertial confinement fusion (ICF), which uses lasers to implode a pellet of fuel in a quest for ignition, has been the focus of the High-Energy-Density Physics (HEDP) group at MIT’s Plasma Science and Fusion Center. This group, including nine former and current MIT students, was crucial to a historic ICF ignition experiment performed in 2021. The results were published this year on the anniversary of that success.

On August 8, 2021, in their quest to produce significant fusion energy, scientists at the National Ignition Facility (NIF), Lawrence Livermore National Laboratory (LLNL), used 192 laser beams to illuminate the inside of a tiny gold cylinder encapsulating a spherical capsule filled with deuterium-tritium fuel. Even though researchers had followed this process many times before, using different parameters, this time the ensuing implosion produced a historic fusion yield of 1.37 megaJoules, as measured by a suite of neutron diagnostics. These included the MIT-developed and analyzed Magnetic Recoil Spectrometer (MRS). This result was published in the journal Physical Review Letters on August 8, the one-year anniversary of the ground-breaking development, unequivocally indicating that the first controlled fusion experiment reached ignition.

A plasma ignites when the internal fusion heating power is high enough to overcome the physical processes that cool the fusion plasma, creating a positive thermodynamic feedback loop that very rapidly increases the plasma temperature. This is governed by the Lawson criterion, named after John D. Lawson who developed the concept in a classified 1955 paper. In the case of ICF, ignition is a state where the fusion plasma can initiate a “fuel burn propagation” into the surrounding dense and cold fuel, enabling the possibility of high fusion-energy gain.

“This historic result certainly demonstrates that the ignition threshold is a real concept, with well-predicted theoretical calculations, and that a fusion plasma can be ignited in a laboratory,” says Johan Frenje, the HEDP Division Head.

By providing and using a dozen diagnostics, implemented by MIT PhD students and staff, which have been critical for assessing the performance of an implosion, the HEDP division has contributed to the success of the ignition program at the NIF for more than a decade. The hundreds of co-authors on the paper attest to the collaborative effort that went into this milestone. MIT’s contributors included the only student co-authors.

“The students are responsible for implementing and using a diagnostic to obtain data important to the ICF program at the NIF, says Frenje. “Being responsible for running a diagnostic at the NIF has allowed them to actively participate in the scientific dialog and thus get directly exposed to cutting-edge science.”

“Lawson Criterion for Ignition Exceeded in an Inertial Fusion Experiment” by H. Abu-Shawareb et al. (Indirect Drive ICF Collaboration), 8 August 2022, Physical Review Letters.
DOI: 10.1103/PhysRevLett.129.075001

Students involved from the MIT Department of Physics were Neel Kabadi, Graeme Sutcliffe, Tim Johnson, Jacob Pearcy, and Ben Reichelt; students from the Department of Nuclear Science and Engineering included Brandon Lahmann, Patrick Adrian, and Justin Kunimune.

In addition, former student Alex Zylstra PhD ’15, now a physicist at LLNL, was the experimental lead of this record implosion experiment.

8 Comments on "MIT Contributes to Success of Historic Fusion Ignition Experiment"

  1. … what would one expect from a humans… still stuck in a …

  2. I’ve got an idea. Once you guys figure out fusion, why not just hand it all over to china.

    • … hand it to all of humans, like Tesla was thinking he was building a new better world… but this is what we end up with…
      Some people ask them self if there is no travelers from future, but travel future is possible, then… one way it is possible is… and many things you got handed in…

  3. “The internal fusion heating power is high enough to overcome the physical processes that cool the fusion plasma, creating a positive thermodynamic feedback loop that very rapidly increases the plasma temperature”

    This “thermodynamic feedback loop” is created with all the electricity humans pump into the reaction. When will humans get to stop their input so the reaction is self-sustaining? If the power is cut off, so is the fusion.

    When quarks get separated, gamma rays are created. It isn’t the matter getting heated that creates the gamma rays, it is the catalyst that keeps the reaction going that are the gamma rays. Once quarks get separated from a sufficient enough reaction, it is the sheer density and pressure of space that keeps the quarks apart indefinitely. Space is able to overcome the strong force between quarks and the sterile electron neutrinos that make up the absolute zero field we live in. Black holes are absolute minimum entropy plasma that use nothing but quarks and space as the catalyst to exist. Being the most powerful objects in the universe, they are going to emit the strongest electromagnetic radiation in the universe which is why they are optically invisible. Eventually, they do create light by creating neutrons on the surface.

    To truly understand the most efficient reaction in the universe, it must be realized what the catalyst for the reaction will be.

    • 1. Topological vortex and anti-vortex field pairs generate or annihilate at the limit points, and encounter, split or merge at the bifurcation points of the 3-dimensional vector order parameter. They can form unstable point defects system.
      2. The most raw field and interaction in the universe can be written in terms of the topological vortex and anti-vortex field pairs.
      3. The gravitation that comes from the topological vortex and anti-vortex field pairs is the beginning of all things, and is the most raw power for maintaining and connecting the world.
      4. The unified field theory can be written in terms of the interaction for topological vortex and anti-vortex field pairs that is topological vortex and anti-vortex field = matter and anti-matter = monopole particles = graviton.

  4. Pretty good for a “tech” school.

  5. Confine the energy in a box where the energy waves are in resonance. Then it will be self sustaining. N layered wave equation https://link.springer.com/article/10.1007/BF02325585

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