England RJ, Filippetto D, Torrisi G, Bacci A, Della Valle G, Mascali D, Mauro GS, Sorbello G, Musumeci P, Scheuer J, Cowan B, Schachter L, Huang YC, Niedermayer U, Kimura WD, Li R, Ishebeck R, Simakov E, Hommelhoff P, Byer R (2022)
Publication Language: English
Publication Type: Journal article
Publication year: 2022
Article Number: 2203.08981
URI: https://arxiv.org/abs/2203.08981
Particle acceleration in microstructures driven by ultrafast solid state lasers is a rapidly evolving area of advanced accelerator research, leading to a variety of concepts based on planar-symmetric dielectric gratings, hollow core fibers, photonic crystals, and plasmonic meta-surfaces. This approach leverages well-established industrial fabrication capabilities and the commercial availability of tabletop lasers to reduce cost, with demonstrated axial accelerating fields in the GV/m range. Wide-ranging international efforts have significantly improved understanding of gradient limits, structure design, particle focusing and transport, staging, and development of compatible low-emittance electron sources. With a near-term focus on low-current MeV-scale applications for compact scientific and medical instruments, as well as novel diagnostics capabilities, structure-based laser-driven accelerators have several key benefits that warrant consideration for future high-energy physics machines, including low beamstrahlung energy loss, modest power requirements, stability, and readiness of supporting technologies.
APA:
England, R.J., Filippetto, D., Torrisi, G., Bacci, A., Della Valle, G., Mascali, D.,... Byer, R. (2022). Laser-Driven Structure-Based Accelerators. arXiv.
MLA:
England, R. Joel, et al. "Laser-Driven Structure-Based Accelerators." arXiv (2022).
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