Your search keyword '"Thomas AGR"' showing total 4 results

1. The influence of laser focusing conditions on the direct laser acceleration of electrons

Author

Tang, H, Tangtartharakul, K, Babjak, R, Yeh, I-L, Albert, F, Chen, H, Campbell, PT, Ma, Y, Nilson, PM, Russell, BK, Shaw, JL, Thomas, AGR, Vranic, M, Arefiev, AV, and Willingale, L

Subjects

Nuclear and Plasma Physics, Physical Sciences, Affordable and Clean Energy, direct laser acceleration, laser-plasma interaction, electron acceleration, Fluids & Plasmas, Physical sciences

Abstract

Direct laser acceleration of electrons during a high-energy, picosecond laser interaction with an underdense plasma has been demonstrated to be substantially enhanced by controlling the laser focusing geometry. Experiments using the OMEGA EP facility measured electrons accelerated to maximum energies exceeding 120 times the ponderomotive energy under certain laser focusing, pulse energy, and plasma density conditions. Two-dimensional particle-in-cell simulations show that the laser focusing conditions alter the laser field evolution, channel fields generation, and electron oscillation, all of which contribute to the final electron energies. The optimal laser focusing condition occurs when the transverse oscillation amplitude of the accelerated electron in the channel fields matches the laser beam width, resulting in efficient energy gain. Through this observation, a simple model was developed to calculate the optimal laser focal spot size in more general conditions and is validated by experimental data.

Published

2024

2. 2020 roadmap on plasma accelerators

Author

Albert, F, Couprie, ME, Debus, A, Downer, MC, Faure, J, Flacco, A, Gizzi, LA, Grismayer, T, Huebl, A, Joshi, C, Labat, M, Leemans, WP, Maier, AR, Mangles, SPD, Mason, P, Mathieu, F, Muggli, P, Nishiuchi, M, Osterhoff, J, Rajeev, PP, Schramm, U, Schreiber, J, Thomas, AGR, Vay, JL, Vranic, M, and Zeil, K

Subjects

plasma accelerators, laser&#8211, plasma interactions, laser wakefield acceleration, particle beams, strong field QED, free electron lasers, Fluids & Plasmas, Physical Sciences

Abstract

Plasma-based accelerators use the strong electromagnetic fields that can be supported by plasmas to accelerate charged particles to high energies. Accelerating field structures in plasma can be generated by powerful laser pulses or charged particle beams. This research field has recently transitioned from involving a few small-scale efforts to the development of national and international networks of scientists supported by substantial investment in large-scale research infrastructure. In this New Journal of Physics 2020 Plasma Accelerator Roadmap, perspectives from experts in this field provide a summary overview of the field and insights into the research needs and developments for an international audience of scientists, including graduate students and researchers entering the field.

Published

2021

3. Relativistic plasma physics in supercritical fields

Author

Zhang, P, Bulanov, SS, Seipt, D, Arefiev, AV, and Thomas, AGR

Subjects

physics.plasm-ph, hep-ph, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Classical Physics, Fluids & Plasmas

Abstract

Since the invention of chirped pulse amplification, which was recognized by a Nobel Prize in physics in 2018, there has been a continuing increase in available laser intensity. Combined with advances in our understanding of the kinetics of relativistic plasma, studies of laser-plasma interactions are entering a new regime where the physics of relativistic plasmas is strongly affected by strong-field quantum electrodynamics (QED) processes, including hard photon emission and electron-positron (e-e+) pair production. This coupling of quantum emission processes and relativistic collective particle dynamics can result in dramatically new plasma physics phenomena, such as the generation of dense e-e+ pair plasma from near vacuum, complete laser energy absorption by QED processes, or the stopping of an ultra-relativistic electron beam, which could penetrate a cm of lead, by a hair's breadth of laser light. In addition to being of fundamental interest, it is crucial to study this new regime to understand the next generation of ultra-high intensity laser-matter experiments and their resulting applications, such as high energy ion, electron, positron, and photon sources for fundamental physics studies, medical radiotherapy, and next generation radiography for homeland security and industry.

Published

2020

4. Relativistic plasma physics in supercritical fields

Author

Zhang, P, Bulanov, SS, Seipt, D, Arefiev, AV, and Thomas, AGR

Subjects

physics.plasm-ph, hep-ph, Fluids & Plasmas, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Classical Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics

Abstract

Since the invention of chirped pulse amplification, which was recognized by a Nobel Prize in physics in 2018, there has been a continuing increase in available laser intensity. Combined with advances in our understanding of the kinetics of relativistic plasma, studies of laser-plasma interactions are entering a new regime where the physics of relativistic plasmas is strongly affected by strong-field quantum electrodynamics (QED) processes, including hard photon emission and electron-positron (e-e+) pair production. This coupling of quantum emission processes and relativistic collective particle dynamics can result in dramatically new plasma physics phenomena, such as the generation of dense e-e+ pair plasma from near vacuum, complete laser energy absorption by QED processes, or the stopping of an ultra-relativistic electron beam, which could penetrate a cm of lead, by a hair's breadth of laser light. In addition to being of fundamental interest, it is crucial to study this new regime to understand the next generation of ultra-high intensity laser-matter experiments and their resulting applications, such as high energy ion, electron, positron, and photon sources for fundamental physics studies, medical radiotherapy, and next generation radiography for homeland security and industry.

Published

2020