The Effect of Plasma Density Gradient on the Direct Laser Acceleration of Electrons
ORAL
Abstract
Direct laser acceleration (DLA) is capable of generating superponderomotive energy electrons to hundreds of MeV, as well as secondary particles and radiation from high-intensity picosecond laser pulses interacting with underdense plasma. Experiments performed on the OMEGA EP facility using apodized beams and supersonic gas nozzle targets demonstrate the sensitivity of the complex process of DLA to the gradient of the plasma density ramps. 2D particle-in-cell OSIRIS simulations mimic the interaction using different plasma density profiles and provide insight into the laser channel creation, laser fields evolution, as well as the significant effect of the sheath fields on the corresponding electron dynamics. Our results show an optimal plasma density gradient and a path towards optimizing DLA conditions.
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Presenters
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Hongmei Tang
University of Michigan
Authors
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Hongmei Tang
University of Michigan
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Veronica Contreras
University of Michigan
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Robert Babjak
University of Lisbon
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Felicie Albert
Lawrence Livermore Natl Lab
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Hui A Chen
Lawrence Livermore National Laboratory, LLNL
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Paul T Campbell
University of Michigan
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Yong Ma
University of Michigan
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Philip M Nilson
Lab for Laser Energetics, Laboratory for Laser Energetics
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Brandon K Russell
University of Michigan
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Jessica Shaw
University of Rochester Laboratory for Laser Energetics, University of Rochester
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Kavin Tangtartharakul
University of California, San Diego, UC San Diego
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I-Lin Yeh
UC San Diego
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Alex V Arefiev
University of California, San Diego
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Marija Vranic
Instituto Superior Tecnico
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Louise Willingale
University of Michigan