First Light Fusion (‘First Light’) has achieved a new experimental milestone at the European Synchrotron Radiation Facility (ESRF) in Grenoble, France. First Light scientists, in collaboration with the University of Oxford’s Department of Engineering Science, performed an experiment on the ID19 beamline to investigate the formation and transit of shock waves through some of First Light Fusion’s amplifiers. First Light’s amplifier technology is central to its unique approach to inertial fusion. The amplifier focuses the input energy from a projectile, boosting the pressure from the impact to create a fusion reaction from its output.
The experimental team consisted of researchers from First Light and the University of Oxford, supported by two summer internship students from the University of Oxford funded by the AMPLIFI Prosperity Partnership. Over two days, the team used a single-stage meso-scale gas launcher to fire aluminum projectiles at speeds around 800 m/s into different types of amplifiers. A diagnostic technique called ‘X-ray phase contrast imaging’[1] was then used to capture the shock dynamics occurring inside the amplifier and the resulting shock exiting the amplifier into an attached plastic sample.
The experiment was highly successful, enabling the team to capture high quality images of the shock formation and motion. This data will be used to validate the performance of First Light’s amplifiers by comparing the results with numerical simulations of the experiment done with state-of-the-art hydrodynamics codes. This will enable high quality benchmarking of the effect of material strength on the amplifier performance at these velocity regimes.
The Prosperity Partnership, jointly funded by the UK Research and Innovation (UKRI) and First Light Fusion, sponsors critical research into inertial fusion energy. In collaboration with Imperial College London, the University of York, the University of Oxford and Mach42 Ltd (formerly Machine Discovery), it aims to foster academic collaboration, provide valuable upskilling and training opportunities, and ultimately solve the problem of fusion energy.
Francisco Suzuki-Vidal, Lead of the Collaborative Experiments Group at First Light Fusion, said: “I am really pleased with the results of this latest collaboration with Oxford University and the ESRF. The progress the team made with these experiments is a crucial step in our journey to delivering commercial fusion at scale. We look forward to continuing working with our academic and industry partners through our Prosperity Partnership AMPLIFI on more ground-breaking research in the future.”
Alexander Rack, Principal Scientist of Beamline ID19 at ESRF, said: “These are fantastic experiments exploiting the unique properties of our facilities, i.e. intense hard X-rays to record ultra-slow motion X-ray videos of what happens inside a shock amplifier.”
Daniel Eakins, Professor of Engineering Science, said: “It’s exceptionally rewarding to see the techniques we’ve developed successfully applied to freeze shock waves in their tracks.
Visualizing how these waves interact and develop within the amplifier is key to understanding and optimizing their behavior. I’m excited to see what other physics the Partnership uncovers as we push these experiments to much higher velocity conditions.”
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