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@ARTICLE{Schroeder:600408,
author = {Schroeder, Chris and Albert, Félicie and Benedetti, Marc
and Bromage, Jake and Bruhwiler, D. and Bulanov, S. S. and
Campbell, Graeme and Cook, Cameron John and Cros, Brigitte
and Downer, M. C. and Esarey, E. and Froula, D. H. and
Fuchs, Maximilian and Geddes, C. G. R. and Gessner, S. J.
and Gonsalves, Anthony Joseph and Hogan, M. J. and Hooker,
Simon and Huebl, A. and Jing, C. and Joshi, Suresh Chandra
and Krushelnick, Karl and Leemans, W. P. and Lehe, R. and
Maier, Andre and Milchberg, H. M. and Mori, W. B. and
Nakamura, Katsuro and Osterhoff, J. and Palastro, J. P. and
Palmer, M. and Poder, K. and Power, J. G. and Shadwick, B.
A. and Terzani, D. and Thevenet, M. and Thomas, Andrew and
van Tilborg, Jeroen and Turner, M. and Vafaei-Najafabadi, N.
and Vay, J.-L. and Zhou, Tao and Zuegel, J.},
title = {{L}inear colliders based on laser-plasma accelerators},
journal = {Journal of Instrumentation},
volume = {18},
number = {06},
issn = {1748-0221},
address = {London},
publisher = {Inst. of Physics},
reportid = {PUBDB-2023-07965, arXiv:2203.08366},
pages = {T06001},
year = {2023},
note = {Contribution to Snowmass 2021, Accelerator Frontier},
abstract = {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.},
month = {Jul},
date = {2022-07-17},
organization = {Snowmass 2021, Seattle (United
States), 17 Jul 2022 - 26 Jul 2022},
keywords = {Accelerator Applications (autogen) / Wake-field
acceleration (laser-driven, electron-driven) (autogen)},
cin = {M / MPA / MPA4 / MPA1},
ddc = {610},
cid = {I:(DE-H253)M-20120731 / I:(DE-H253)MPA-20200816 /
I:(DE-H253)MPA4-20220318 / I:(DE-H253)MPA1-20210408},
pnm = {621 - Accelerator Research and Development (POF4-621)},
pid = {G:(DE-HGF)POF4-621},
experiment = {EXP:(DE-MLZ)NOSPEC-20140101},
typ = {PUB:(DE-HGF)8 / PUB:(DE-HGF)16},
eprint = {2203.08366},
howpublished = {arXiv:2203.08366},
archivePrefix = {arXiv},
SLACcitation = {$\%\%CITATION$ = $arXiv:2203.08366;\%\%$},
UT = {WOS:001026537200006},
doi = {10.1088/1748-0221/18/06/T06001},
url = {https://bib-pubdb1.desy.de/record/600408},
}
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