强激光与粒子束
2023, 35(1): 012008
Author Affiliations
Abstract
1 Laboratoire pour l’Utilisation des Lasers Intenses, CNRS, Ecole Polytechnique, 91128 Palaiseau, France
2 CEA-CESTA, F-33116 Le Barp, France
Emerging multi-PW-class lasers and their envisioned laser–plasma interaction applications in unprecedented intensity regimes set a very demanding frame for the precise understanding of the finest properties of these systems. In this work we present a synthesis of simulation studies on a series of less known or even completely disregarded spatiotemporal effects that could potentially impact greatly the performances of high-intensity lasers.
spatiotemporal coupling Ti:sapphire lasers ultra-intense lasers High Power Laser Science and Engineering
2022, 10(1): 010000e5
Author Affiliations
Abstract
Laboratory for Laser Energetics, University of Rochester, Rochester, NY14623, USA
Optical parametric chirped-pulse amplification implemented using multikilojoule Nd:glass pump lasers is a promising approach for producing ultra-intense pulses (>1023 W/cm2). We report on the MTW-OPAL Laser System, an optical parametric amplifier line (OPAL) pumped by the Nd:doped portion of the multi-terawatt (MTW) laser. This midscale prototype was designed to produce 0.5-PW pulses with technologies scalable to tens of petawatts. Technology choices made for MTW-OPAL were guided by the longer-term goal of two full-scale OPALs pumped by the OMEGA EP to produce 2 × 25-PW beams that would be co-located with kilojoule-nanosecond ultraviolet beams. Several MTW-OPAL campaigns that have been completed since “first light” in March 2020 show that the laser design is fundamentally sound, and optimization continues as we prepare for “first-focus” campaigns later this year.
nonlinear optics optical parametric chirped-pulse amplification ultra-intense lasers ultrafast lasers High Power Laser Science and Engineering
2021, 9(4): 01000e63
Author Affiliations
Abstract
1 Institute of Nuclear Fusion, Polytechnic University of Madrid, Spain
2 Applied Physics Division, Soreq NRC Yavne, Israel
3 42 Beery, Rehovot, Israel
The laser-induced relativistic shock waves are described. The shock waves can be created directly by a high irradiance laser or indirectly by a laser acceleration of a foil that collides with a second static foil. A special case of interest is the creation of laser-induced fusion where the created alpha particles create a detonation wave. A novel application is suggested with the shock wave or the detonation wave to ignite a pre-compressed target. In particular, the deuterium–tritium fusion is considered. It is suggested that the collision of two laser accelerated foils might serve as a novel relativistic accelerator for bulk material collisions.
fast ignition fast ignition laser piston model laser piston model relativistic shock waves relativistic shock waves ultra-intense lasers ultra-intense lasers High Power Laser Science and Engineering
2016, 4(3): 03000e25