Your search keyword '"Michael Litos"' showing total 3 results

1. Demonstration of a positron beam-driven hollow channel plasma wakefield accelerator

Author

Spencer Gessner, Erik Adli, James M. Allen, Weiming An, Christine I. Clarke, Chris E. Clayton, Sebastien Corde, J. P. Delahaye, Joel Frederico, Selina Z. Green, Carsten Hast, Mark J. Hogan, Chan Joshi, Carl A. Lindstrøm, Nate Lipkowitz, Michael Litos, Wei Lu, Kenneth A. Marsh, Warren B. Mori, Brendan O’Shea, Navid Vafaei-Najafabadi, Dieter Walz, Vitaly Yakimenko, and Gerald Yocky

Subjects

Science

Abstract

Plasma wakefield accelerators produce gradients that are orders of magnitude larger than in conventional particle accelerator, but beams tend to be disrupted by transverse forces. Here the authors create an extended hollow plasma channel, which accelerates positrons without generating transverse forces.

Published

2016

2. Dissipation of electron-beam-driven plasma wakes

Author

Spencer Gessner, Vitaly Yakimenko, Jorge Vieira, V. K. Khudyakov, Rafal Zgadzaj, Michael C. Downer, Michael Litos, A. P. Sosedkin, T. Silva, Konstantin Lotov, Mark Hogan, Zhengyan Li, and James Allen

Subjects

Science, General Physics and Astronomy, FOS: Physical sciences, Electron, 7. Clean energy, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Linear particle accelerator, Article, 010305 fluids & plasmas, law.invention, law, Physics::Plasma Physics, 0103 physical sciences, 010306 general physics, lcsh:Science, Physics, Multidisciplinary, Particle accelerator, General Chemistry, Plasma, Laser-produced plasmas, Dissipation, Physics - Plasma Physics, Computational physics, Plasma Physics (physics.plasm-ph), Cathode ray, Lithium Tokamak Experiment, Physics::Accelerator Physics, lcsh:Q, Beam (structure), Plasma-based accelerators

Abstract

Metre-scale plasma wakefield accelerators have imparted energy gain approaching 10 gigaelectronvolts to single nano-Coulomb electron bunches. To reach useful average currents, however, the enormous energy density that the driver deposits into the wake must be removed efficiently between shots. Yet mechanisms by which wakes dissipate their energy into surrounding plasma remain poorly understood. Here, we report picosecond-time-resolved, grazing-angle optical shadowgraphic measurements and large-scale particle-in-cell simulations of ion channels emerging from broken wakes that electron bunches from the SLAC linac generate in tenuous lithium plasma. Measurements show the channel boundary expands radially at 1 million metres-per-second for over a nanosecond. Simulations show that ions and electrons that the original wake propels outward, carrying 90 percent of its energy, drive this expansion by impact-ionizing surrounding neutral lithium. The results provide a basis for understanding global thermodynamics of multi-GeV plasma accelerators, which underlie their viability for applications demanding high average beam current., Plasma wakefield accelerators promise compact, affordable future particle accelerators, but require deposition of enormous energy into a small volume. Here, the authors measure and simulate how this energy transfers from the wake into surrounding plasma, a process that ultimately governs the accelerator’s repetition rate.

Published

2020

3. High-field plasma acceleration in a high-ionization-potential gas

Author

Navid Vafaei-Najafabadi, Chan Joshi, Michael Litos, C. E. Clayton, Jean-Pierre Delahaye, Erik Adli, S. Z. Green, Wei Lu, Mark Hogan, K. A. Marsh, Christine Clarke, Spencer Gessner, Sebastien Corde, D.R. Walz, Warren Mori, Vitaly Yakimenko, Weiming An, James Allen, J. Frederico, B Clausse, Laboratoire d'optique appliquée (LOA), École Nationale Supérieure de Techniques Avancées (ENSTA Paris)-École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS), Department of Physics [Oslo], Faculty of Mathematics and Natural Sciences [Oslo], University of Oslo (UiO)-University of Oslo (UiO), SLAC National Accelerator Laboratory (SLAC), Stanford University, University of California [Los Angeles] (UCLA), University of California, Department of Physics and Astronomy [UCLA, Los Angeles], University of California-University of California, and Tsinghua University [Beijing] (THU)

Subjects

0301 basic medicine, Science, General Physics and Astronomy, 7. Clean energy, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, 03 medical and health sciences, Acceleration, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Physics::Plasma Physics, law, 0103 physical sciences, 010306 general physics, [PHYS]Physics [physics], Physics, Multidisciplinary, Particle accelerator, General Chemistry, Plasma, Plasma acceleration, 030104 developmental biology, Cathode ray, Physics::Accelerator Physics, Head (vessel), Particle, Ionization energy, Atomic physics

Abstract

Plasma accelerators driven by particle beams are a very promising future accelerator technology as they can sustain high accelerating fields over long distances with high energy efficiency. They rely on the excitation of a plasma wave in the wake of a drive beam. To generate the plasma, a neutral gas can be field-ionized by the head of the drive beam, in which case the distance of acceleration and energy gain can be strongly limited by head erosion. Here we overcome this limit and demonstrate that electrons in the tail of a drive beam can be accelerated by up to 27 GeV in a high-ionization-potential gas (argon), boosting their initial 20.35 GeV energy by 130%. Particle-in-cell simulations show that the argon plasma is sustaining very high electric fields, of ∼150 GV m−1, over ∼20 cm. The results open new possibilities for the design of particle beam drivers and plasma sources., Plasma accelerators driven by particle beams are a promising technology, but the acceleration distance and energy gain are strongly limited by head erosion in a high-ionization-potential gas. Here the authors observe up to 130% energy boost in a self-focused electron beam, with limited head erosion.

Published

2016