Abstract
Plasma accelerators driven by high-power lasers can provide high-energy electron beams on a dramatically smaller scale than conventional radio-frequency accelerators. However, the performance of these accelerators is fundamentally limited by the diffraction of the laser. Laser-generated plasma waveguides can mitigate this problem and, combined with a controlled injection method for electrons, highlight the potential of novel laser-plasma optics.
Modern laser systems with peak powers at the terawatt or even petawatt level have unlocked access to entirely new regimes of optics, which have been coined relativistic optics1 or plasma optics2. When focused onto a micrometer spot size, the field gradients within the laser can reach many teravolts per meter, which is enough to accelerate electrons to near lightspeed within a single cycle. Not only are these particles immediately ionized and form a plasma, but their increased momentum also modifies the refractive index of the medium. In a plasma at atmospheric density the laser is locally slowed down, curving its wavefront to focus. This relativistic self-focusing counteracts natural diffraction and allows the laser pulses to maintain their extremely high intensity over several Rayleigh lengths1.
Meanwhile, the interplay between excited electrons and quasi-stationary ions leads to the formation of plasma oscillations in the wake of the laser pulses. These wakefields possess very high fields of their own. But in contrast to the transversely oriented laser fields, the plasma wakefields contain a strong longitudinal component (~100 GV/m). This is many orders of magnitude more than accelerators run at radio-frequency achieve and a laser wakefield accelerator (LWFA) can accelerate electrons to GeV energies within a centimeter3,4.
The energy gain in LWFA is limited by the “three D’s”, namely the available laser energy (depletion), the phase slip between electrons and the wakefield-exciting laser (dephasing) and the intensity of the laser (diffraction). To reduce dephasing one has to lower the plasma density, but this in turn weakens the self-focusing effect significantly. To overcome this deadlock one needs to guide the laser in some alternative manner. This was first successfully demonstrated using discharge-generated plasma channels5, but these devices have only found limited use due to their complexity. More recently, all-optical techniques have gained traction, when several groups demonstrated efficient guiding in plasma channels generated by Bessel beams6,7,8. Conveniently, these line-focused guiding beams can often be derived from parts of the high-power laser that drives the plasma accelerator.
Now, writing in this issue of Light: Science & Applications, a team of scientists from Laboratoire d’Optique Appliquée in France has successfully combined an all-optical plasma waveguide with a state-of-the-art laser wakefield accelerator9. The guiding channel is generated by a 1.5 mJ, 30 fs laser pulse, which is intense enough to create a plasma via field ionization. The plasma then expands radially, forming a waveguide. After 2 nanoseconds, the thousand times more powerful 50 TW drive beam is sent into the plasma and drives a plasma wakefield, as sketched in Fig. 1.
Schematic view of the experimental setup for plasma waveguide and laser-driven wakefield acceleration
The authors find that the drive beam can be efficiently guided over 15 mm, which is about 20 times the Rayleigh length of the focused laser in vacuum. Maintaining high intensity over this distance allowed the laser wakefield to accelerate electrons to GeV-level energy, yet with significant energy spread. Similar results were recently reported by a group of researchers from the United Kingdom and the United States, who used an even more powerful 300 TW laser and reached beam energies of up to 4 GeV13, holograms14 and the waveguides discussed in this article, lasers can also be used for longitudinal plasma sha**15, which would allow for all-optical guiding, injection, and acceleration.
References
Mourou, G. A., Tajima, T. & Bulanov, S. V. Optics in the relativistic regime. Rev. Mod. Phys. 78, 309–371 (2006).
Gibbon, P. Cleaner petawatts with plasma optics. Nat. Phys. 3, 369–370 (2007).
Esarey, E., Schroeder, C. B. & Leemans, W. P. Physics of laser-driven plasma-based electron accelerators. Rev. Mod. Phys. 81, 1229–1285 (2009).
Hooker, S. M. Developments in laser-driven plasma accelerators. Nat. Photonics 7, 775–782 (2013).
Leemans, W. P. et al. GeV electron beams from a centimetre-scale accelerator. Nat. Phys. 2, 696–699 (2006).
Shalloo, R. J. et al. Hydrodynamic optical-field-ionized plasma channels. Phys. Rev. E 97, 053203 (2018).
Smartsev, S. et al. Axiparabola: a long-focal-depth, high-resolution mirror for broadband high-intensity lasers. Opt. Lett. 44, 3414–3417 (2019).
Miao, B. et al. Optical guiding in meter-scale plasma waveguides. Phys. Rev. Lett. 125, 074801 (2020).
Oubrerie, K. et al. Controlled acceleration of GeV electron beams in an all-optical plasma waveguide. Light Sci. Appl. 11, 180 (2022).
Miao, B. et al. Multi-GeV electron bunches from an all-optical laser wakefield accelerator. Print at https://doi.org/10.48550/ar**v.2112.03489 (2021).
Buck, A. et al. Shock-front injector for high-quality laser-plasma acceleration. Phys. Rev. Lett. 110, 185006 (2013).
Götzfried, J. et al. Physics of high-charge electron beams in laser-plasma wakefields. Phys. Rev. X 10, 041015 (2020).
Thaury, C. et al. Plasma mirrors for ultrahigh-intensity optics. Nat. Phys. 3, 424–429 (2007).
Leblanc, A. et al. Plasma holograms for ultrahigh-intensity optics. Nat. Phys. 13, 440–443 (2017).
Foerster, F. M. et al. Stable and high quality electron beams from staged laser and plasma wakefield accelerators. Print at https://doi.org/10.48550/ar**v.2206.00507 (2022).
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Döpp, A. Plasma optics improving plasma accelerators. Light Sci Appl 11, 239 (2022). https://doi.org/10.1038/s41377-022-00925-2
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DOI: https://doi.org/10.1038/s41377-022-00925-2
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