Scaling of laser-driven electron and proton acceleration as a function of laser pulse duration, energy, and intensity in the multi-picosecond regime

Raspberry Simpson ,F Albert,M J.-E Manuel,A Mackinnon,S Kerr,D Neely,A Haid,J A Frenje,T Ma,A Aghedo,R Cauble,I Pagano,A Pak,K Charron,G J Williams,D Mariscal,R Costa,Chris Armstrong ,A G Macphee ,B C Stuart ,Dean Rusby ,L A Winslow ,Nuno Lemos ,Scott Andrews ,Mitchell Sinclair ,M Gatu Johnson ,Paul M King ,Elizabeth Grace ,Bettina Fischer ,Kirk Flippo ,Stephen M Maricle ,Graeme Scott

doi:10.1063/5.0023612

Scaling of laser-driven electron and proton acceleration as a function of laser pulse duration, energy, and intensity in the multi-picosecond regime

Raspberry Simpson , F Albert + Show 30 more

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Journal: Physics of Plasmas	Publication Date: Jan 1, 2021
Citations: 21	License type: publisher-specific-oa

Affiliation: Massachusetts Institute of Technology, Lawrence Livermore National Laboratory, General Atomics (United States), Rutherford Appleton Laboratory, Fusion Academy, Plasma Technology (United States), Florida Agricultural and Mechanical University, The University of Texas at Austin, University of California, Los Angeles, Georgia Institute of Technology, Los Alamos National Laboratory

#Function Of Pulse Duration #Proton Acceleration #Electron Acceleration #Laser Energy #Laser Intensity #Laser-driven Proton Acceleration #Laser-driven Electron Acceleration #Preplasma Conditions #Laser-driven Proton #Laser-driven Electron

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A scaling study of short-pulse laser-driven proton and electron acceleration was conducted as a function of pulse duration, laser energy, and laser intensity in the multi-picosecond (ps) regime (∼0.8 ps–20 ps). Maximum proton energies significantly greater than established scaling laws were observed, consistent with observations at other multi-ps laser facilities. In addition, maximum proton energies and electron temperatures in this regime were found to be strongly dependent on the laser pulse duration and preplasma conditions. A modified proton scaling model is presented that is able to better represent the accelerated proton characteristics in this multi-ps regime.

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Scaling of laser-driven electron and proton acceleration as a function of laser pulse duration, energy, and intensity in the multi-picosecond regime