Description
The most impressive experimental results (see [1, 2]) until now in electron accelerating by a wakefield, excited in a plasma, have been achieved using capillary-generated plasma. Plasma-wakefield acceleration provides high accelerating gradients (see [1, 3, 4]), promises compact accelerators of high-brightness and high-energy electron beams. Applications of plasma-wakefield accelerators, in particular, particle colliders (see [5]) and free-electron lasers demand low energy spread beams, their small emittance, high current of accelerated bunches, large transformer ratio and high-efficiency operation. Achievement of these requires plateau formation on both the accelerating field for witness-bunch and the decelerating fields for driver-bunches. As it is known plateau formation is possible by controlled beam loading with careful shaping current profile and beam charge selection. We will demonstrate by numerical simulation by PIC code such optimal beam loading in a linear and blowout electron-driven plasma accelerators. Beams for plasma accelerator are prepared with RF linear accelerator with high beam quality.
Problems of acceleration of positron bunches in plasma (see [6]), focusing and stable transport of electron and positron bunches in plasma (see [7]) are important.
We will investigate in the project problems:
- ideal wakefield plasma lens (due to loading effect) for identical focusing of train of homogeneous bunches or Gaussian bunches depending on their lengths, gaps, charges for stable electron or positron beam propagation in a plasma column;
- optimal beam loading for the self-consistent distributions of a decelerating wakefield of plateau type for a driver-bunch and an accelerating wakefield of plateau type for a witness-bunch during all time of acceleration;
- control of optimal field shape (by loading effect), accelerating electron and positron bunches in plasma wakefield;
- obtaining long accelerated electron bunch of good quality (due to loading effect) in plasma wakefield accelerator at high transformer ratio.
Literature:
1. Leemans W.P., Gonsalves A.J., MaoH.-S. et al. Multi-GeV Electron Beams from Capillary-Discharge-Guided Subpetawatt Laser Pulses in the Self-Trapping Regime. Phys. Rev. Lett. 2014. v. 113. p. 245002.
2. Gonsalves A.J., Nakamura K., Daniels J. et al. Petawatt Laser Guiding and Electron Beam Acceleration to 8 GeV in a Laser-Heated Capillary Discharge Waveguide. Phys. Rev. Lett. 2019. v. 122. p. 084801.
3. Blumenfeld I., Clayton C.E., Decker F.-J. et al. Energy doubling of 42 GeV electrons in a metre-scale plasma wakefield accelerator. Nature, Letters. 2007. v. 445. p. 741-744.
4. Assmann R., Gschwendtner E., Cassou K. et al. High-gradient plasma and laser accelerators. CERN Yellow Reports: Monographs 1. 2022. p. 91.
5. Benedetti C., Bulanov S.S., Esarey E. et al. Linear collider based on laser-plasma accelerators. arXiv preprint arXiv:2203.08366. 2022.
6. Diederichs S., Benedetti C., Thévenet M., Esarey E., Osterhoff J. et al. Self-stabilizing positron acceleration in a plasma column. arXiv preprint arXiv:2206. 2022. 11967.
7. Diederichs S., Benedetti C., Esarey E., Thévenet M., Osterhoff J. et al. Stable electron beam propagation in a plasma column. Physics of Plasmas. 2022. v. 29 (4). p. 043101.
Special Qualifications:
Programming experience is helpful
| Field | B4: Research on Accelerators |
|---|---|
| DESY Place | Hamburg |
| DESY Division | M |
| DESY Group | MPA |
