TY - JOUR
T1 - Progress in Hybrid Plasma Wakefield Acceleration
AU - Hidding, Bernhard
AU - Assmann, Ralph
AU - Bussmann, Michael
AU - Campbell, David
AU - Chang, Yen Yu
AU - Corde, Sébastien
AU - Cabadağ, Jurjen Couperus
AU - Debus, Alexander
AU - Döpp, Andreas
AU - Gilljohann, Max
AU - Götzfried, J.
AU - Foerster, F. Moritz
AU - Haberstroh, Florian
AU - Habib, Fahim
AU - Heinemann, Thomas
AU - Hollatz, Dominik
AU - Irman, Arie
AU - Kaluza, Malte
AU - Karsch, Stefan
AU - Kononenko, Olena
AU - Knetsch, Alexander
AU - Kurz, Thomas
AU - Kuschel, Stephan
AU - Köhler, Alexander
AU - Ossa, Alberto Martinez de la
AU - Nutter, Alastair
AU - Pausch, Richard
AU - Raj, Gaurav
AU - Schramm, Ulrich
AU - Schöbel, Susanne
AU - Seidel, Andreas
AU - Steiniger, Klaus
AU - Ufer, Patrick
AU - Yeung, Mark
AU - Zarini, Omid
AU - Zepf, Matt
N1 - Publisher Copyright:
© 2023 by the authors.
PY - 2023/2/1
Y1 - 2023/2/1
N2 - Plasma wakefield accelerators can be driven either by intense laser pulses (LWFA) or by intense particle beams (PWFA). A third approach that combines the complementary advantages of both types of plasma wakefield accelerator has been established with increasing success over the last decade and is called hybrid LWFA→PWFA. Essentially, a compact LWFA is exploited to produce an energetic, high-current electron beam as a driver for a subsequent PWFA stage, which, in turn, is exploited for phase-constant, inherently laser-synchronized, quasi-static acceleration over extended acceleration lengths. The sum is greater than its parts: the approach not only provides a compact, cost-effective alternative to linac-driven PWFA for exploitation of PWFA and its advantages for acceleration and high-brightness beam generation, but extends the parameter range accessible for PWFA and, through the added benefit of co-location of inherently synchronized laser pulses, enables high-precision pump/probing, injection, seeding and unique experimental constellations, e.g., for beam coordination and collision experiments. We report on the accelerating progress of the approach achieved in a series of collaborative experiments and discuss future prospects and potential impact.
AB - Plasma wakefield accelerators can be driven either by intense laser pulses (LWFA) or by intense particle beams (PWFA). A third approach that combines the complementary advantages of both types of plasma wakefield accelerator has been established with increasing success over the last decade and is called hybrid LWFA→PWFA. Essentially, a compact LWFA is exploited to produce an energetic, high-current electron beam as a driver for a subsequent PWFA stage, which, in turn, is exploited for phase-constant, inherently laser-synchronized, quasi-static acceleration over extended acceleration lengths. The sum is greater than its parts: the approach not only provides a compact, cost-effective alternative to linac-driven PWFA for exploitation of PWFA and its advantages for acceleration and high-brightness beam generation, but extends the parameter range accessible for PWFA and, through the added benefit of co-location of inherently synchronized laser pulses, enables high-precision pump/probing, injection, seeding and unique experimental constellations, e.g., for beam coordination and collision experiments. We report on the accelerating progress of the approach achieved in a series of collaborative experiments and discuss future prospects and potential impact.
KW - LWFA
KW - PWFA
KW - compact particle acceleration
KW - plasma wakefield acceleration
KW - radiation sources
U2 - 10.3390/photonics10020099
DO - 10.3390/photonics10020099
M3 - Review article
AN - SCOPUS:85149067434
SN - 2304-6732
VL - 10
JO - Photonics
JF - Photonics
IS - 2
M1 - 99
ER -