Linear colliders based on laser-plasma accelerators

Schroeder, Chris; Huebl, A.; Geddes, C. G. R.; Fuchs, Maximilian; Bruhwiler, D.; Thomas, Andrew; van Tilborg, Jeroen; Bromage, Jake; Cook, Cameron John; Cros, Brigitte; Campbell, Graeme; Joshi, Suresh Chandra; Zuegel, J.; Nakamura, Katsuro; Poder, K.; Mori, W. B.; Thevenet, M.; Hooker, Simon; Bulanov, S. S.; Gonsalves, Anthony Joseph; Gessner, S. J.; Jing, C.; Shadwick, B. A.; Vafaei-Najafabadi, N.; Hogan, M. J.; Terzani, D.; Krushelnick, Karl; Esarey, E.; Froula, D. H.; Palastro, J. P.; Vay, J.-L.; Osterhoff, J.; Leemans, W. P.; Benedetti, Marc; Zhou, Tao; Milchberg, H. M.; Palmer, M.; Lehe, R.; Downer, M. C.; Power, J. G.; Albert, Félicie; Turner, M.; Maier, Andre

doi:10.1088/1748-0221/18/06/T06001

%0 Journal Article
%A Schroeder, Chris
%A Albert, Félicie
%A Benedetti, Marc
%A Bromage, Jake
%A Bruhwiler, D.
%A Bulanov, S. S.
%A Campbell, Graeme
%A Cook, Cameron John
%A Cros, Brigitte
%A Downer, M. C.
%A Esarey, E.
%A Froula, D. H.
%A Fuchs, Maximilian
%A Geddes, C. G. R.
%A Gessner, S. J.
%A Gonsalves, Anthony Joseph
%A Hogan, M. J.
%A Hooker, Simon
%A Huebl, A.
%A Jing, C.
%A Joshi, Suresh Chandra
%A Krushelnick, Karl
%A Leemans, W. P.
%A Lehe, R.
%A Maier, Andre
%A Milchberg, H. M.
%A Mori, W. B.
%A Nakamura, Katsuro
%A Osterhoff, J.
%A Palastro, J. P.
%A Palmer, M.
%A Poder, K.
%A Power, J. G.
%A Shadwick, B. A.
%A Terzani, D.
%A Thevenet, M.
%A Thomas, Andrew
%A van Tilborg, Jeroen
%A Turner, M.
%A Vafaei-Najafabadi, N.
%A Vay, J.-L.
%A Zhou, Tao
%A Zuegel, J.
%T Linear colliders based on laser-plasma accelerators
%J Journal of Instrumentation
%V 18
%N 06
%@ 1748-0221
%C London
%I Inst. of Physics
%M PUBDB-2023-07965
%M arXiv:2203.08366
%P T06001
%D 2023
%Z Contribution to Snowmass 2021, Accelerator Frontier
%X Laser-plasma accelerators are capable of sustainingaccelerating fields of 10–100 GeV/m, 100–1000 times that ofconventional technology and the highest fields produced by any ofthe widely researched advanced accelerator concepts. Laser-plasmaaccelerators also intrinsically accelerate short particle bunches,several orders of magnitude shorter than that of conventionaltechnology, which leads to reductions in beamstrahlung and, hence,savings in the overall power consumption to reach a desiredluminosity. These properties make laser-plasma accelerators apromising accelerator technology for a more compact, less expensivehigh-energy linear collider providing multi-TeV polarized leptons.In this submission to the Snowmass 2021 Accelerator Frontier, wediscuss the motivation for a laser-plasma-accelerator-based linearcollider, the status of the field, and potential linear colliderconcepts up to 15 TeV. We outline the research and developmentpath toward a collider based on laser-plasma accelerator technology,and highlight near-term and mid-term applications of this technologyon the collider development path. The required experimentalfacilities to carry out this research are described. We concludewith community recommendations developed during Snowmass.
%B Snowmass 2021
%C 17 Jul 2022 - 26 Jul 2022, Seattle (United States)
Y2 17 Jul 2022 - 26 Jul 2022
M2 Seattle, United States
%K Accelerator Applications (autogen)
%K Wake-field acceleration (laser-driven, electron-driven) (autogen)
%F PUB:(DE-HGF)8 ; PUB:(DE-HGF)16
%9 Contribution to a conference proceedingsJournal Article
%U <Go to ISI:>//WOS:001026537200006
%R 10.1088/1748-0221/18/06/T06001
%U https://bib-pubdb1.desy.de/record/600408

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