Linear collider based on laser-plasma accelerators

Benedetti, C.; Bulanov, S. S.; Esarey, E.; Geddes, C. G. R.; Gonsalves, A. J.; Huebl, A.; Lehe, R.; Nakamura, K.; Schroeder, Carl; Terzani, D.; Tilborg, J. van; Turner, M.; Vay, J. -L.; Zhou, T.; Albert, F.; Bromage, J.; Campbell, E. M.; Froula, D. H.; Palastro, J. P.; Zuegel, J.; Bruhwiler, D.; Cook, N. M.; Cros, B.; Downer, M. C.; Fuchs, M.; Shadwick, B. A.; Gessner, S. J.; Hogan, M. J.; Hooker, S. M.; Jing, C.; K., Krushelnick,; Thomas, Alec; Leemans, W. P.; Maier, A. R.; Osterhoff, J.; Poder, K.; Thevenet, M.; Joshi, C.; Mori, W. B.; Milchberg, H. M.; Palmer, M.; Power, J. G.; Vafaei-Najafabadi, N.

doi:10.48550/arxiv.2203.08366

Cited by 2 publications

(3 citation statements)

References 82 publications

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“…The accelerator model works with the density 𝑛 = 10 17 𝑐𝑚 −3 and with the plasma channel which has radius of 22𝜇𝑚. The laser of the accelerator is a 6.5J, 130fs FWHM laser, and it could excite the plasma with the peak accelerating field of 6 GV/m [9]. An proper particle beams of 0.19nC (3kA beams peak current) can be obtained energy above 5 GeV with the efficiency of 20% [9].…”

Section: Electron-positron Collidermentioning

confidence: 99%

“…The laser of the accelerator is a 6.5J, 130fs FWHM laser, and it could excite the plasma with the peak accelerating field of 6 GV/m [9]. An proper particle beams of 0.19nC (3kA beams peak current) can be obtained energy above 5 GeV with the efficiency of 20% [9]. Energy recovery operations could be performs for the energy remain in the laser as well as the plasma.…”

Section: Electron-positron Collidermentioning

confidence: 99%

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Alysis of Laser-Plasma Based Electron-Positron Collider

Liu¹

2023

HSET

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Contemporarily, the collider plays a vital role in research and analysis for high energy physics, particle physics and astrophysics. However, conventional colliders usually need a large budget to operate as well as cover a large area for displacing the facility. With the rapid development of the laser techniques, the laser-plasma accelerator paves a path to accelerate particles in a compact way. On this basis, this paper will analyze the feasibility and recent progress for electron-positron collider realization via the concept of the laser-plasma acceleration. To be specific, the principles behind it will be analyzed initially. To be specific, an intense electromagnetic could make the plasma oscillated due to the pondermotive force, and the electron field created by the oscillation of the plasma could accelerate electrons to high energy. In addition, the possibility of applying laser plasma acceleration in to electron-positron collider is examined. These results shed light on guiding the further exploration of future electron-positron collider.

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Section: Electron-positron Collidermentioning

confidence: 99%

Section: Electron-positron Collidermentioning

confidence: 99%

Alysis of Laser-Plasma Based Electron-Positron Collider

Liu¹

2023

HSET

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“…In conventional accelerators positrons are usually produced via collisions of high energy electrons or photons with solid density high-Z foils (see, e.g., proposed [13][14][15] and operational [11] designs), accumulated in a damping ring, and then transported into the accelerator. Compact, plasma-based accelerators, however, present a set of unique requirements for accelerating positron beams efficiently [16]. The most challenging ones are achieving a low energy spread and divergence, as well as the short duration of the beam so the positrons can be efficiently captured in the plasma wakefield.…”

Section: Introductionmentioning

confidence: 99%

Design study for a compact, two-stage, laser-plasma-based source of positron beams

Amorim

Benedetti

Bulanov

et al. 2023

Plasma Phys. Control. Fusion

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Owing to their large accelerating gradients, plasma-based accelerators have attracted considerable interest as potential drivers for future, compact electron-positron colliders. Despite great progress achieved in plasma-based electron acceleration, positron acceleration still remains a challenging task, with an efficient positron source being the prerequisite for such acceleration. Here a concept for a compact, two-stage plasma-based positron source is discussed. In the first stage the positrons are created by a multi-GeV electron beam produced by a laser-plasma accelerator interacting with a solid density foil. In the second stage the positrons are captured and accelerated in a plasma wave driven by either an electron beam or a laser pulse. Three potential configurations of such a source are considered: (i) A single electron beam is used for both the creation of positrons in the foil and for driving the wakefield in the second stage; (ii) A train of two electron beams is used: the positrons produced by the trailing beam in the foil are captured and accelerated in the second stage by the plasma wave generated by the leading beam; and (iii) A single electron beam is used to produce positrons in the foil and an independent laser pulse is coupled to the second stage to drive the plasma wave. These three configurations show different degrees of effectiveness with positron capture efficiency, varying from less than a percent to almost half of all produced positrons.

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Linear collider based on laser-plasma accelerators

Cited by 2 publications

References 82 publications

Alysis of Laser-Plasma Based Electron-Positron Collider

Alysis of Laser-Plasma Based Electron-Positron Collider

Design study for a compact, two-stage, laser-plasma-based source of positron beams

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