Spin Filter for Polarized Electron Acceleration in Plasma Wakefields

Yitong Wu, Liangliang Ji, Xuesong Geng, Johannes Thomas, Markus Büscher, Alexander Pukhov, Anna Hützen, Lingang Zhang, Baifei Shen, and Ruxin Li

Phys. Rev. Applied 13, 044064 – Published 24 April 2020

Abstract

We propose a filter method to generate electron beams of high polarization from bubble and blow-out wakefield accelerators. The mechanism is based on the idea of identifying all electron-beam subsets with low polarization and filtering them out with an X-shaped slit placed immediately behind the plasma accelerator. To find these subsets we investigate the dependence between the initial azimuthal angle and the spin of single electrons during the trapping process. This dependence shows that transverse electron spins preserve their orientation during injection if they are initially aligned parallel or antiparallel to the local magnetic field. We derive a precise correlation of the local beam polarization as a function of the coordinate and the electron phase angle. Three-dimensional particle-in-cell simulations, incorporating classical spin dynamics, show that the beam polarization can be increased from 35% to about 80% after spin filtering. The injected flux is strongly restricted to preserve the beam polarization; for example, less than 1 kA in Wen et al. [Phys. Rev. Lett. 122, 214801 (2019)]. This limitation is removed by use of the proposed filter mechanism. The robustness of the method is discussed in terms of drive-beam fluctuations, jitters, the thickness of the filter, and the initial temperature. This idea marks an efficient and simple strategy to generate energetic polarized electron beams on the basis of wakefield acceleration.

Received 15 December 2019
Accepted 31 March 2020

DOI:https://doi.org/10.1103/PhysRevApplied.13.044064

Physics Subject Headings (PhySH)

High intensity laser-plasma interactions Laser driven electron acceleration Laser wakefield acceleration Particle acceleration in plasmas

Particle-in-cell methods

Plasma Physics

Authors & Affiliations

Yitong Wu^1,2, Liangliang Ji^1,3,*, Xuesong Geng ^1,2, Johannes Thomas ⁴, Markus Büscher ^5,6, Alexander Pukhov⁴, Anna Hützen ^5,6, Lingang Zhang¹, Baifei Shen^1,3,7,†, and Ruxin Li^1,3,8,‡

¹State Key Laboratory of High Field Laser Physics, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, 201800 Shanghai, China
²Center of Materials Science and Optoelectronics Engineering, University of Chinese Academy of Sciences, 100049 Beijing, China
³CAS Center for Excellence in Ultra-intense Laser Science, 201800 Shanghai, China
⁴Institut für Theoretische Physik I, Heinrich-Heine-Universität Düsseldorf, Universitätsstraße 1, 40225 Düsseldorf, Germany
⁵Peter Grünberg Institut (PGI-6), Forschungszentrum Jülich, Wilhelm-Johnen-Straße 1, 52425 Jülich, Germany
⁶Institut für Laser- und Plasmaphysik, Heinrich-Heine-Universität Düsseldorf, Universitätsstraße 1, 40225 Düsseldorf, Germany
⁷Shanghai Normal University, 200234 Shanghai, China
⁸Shanghai Tech University, 201210 Shanghai, China

^*jill@siom.ac.cn
^†bfshen@mail.shcnc.ac.cn
^‡ruxinli@mail.siom.ac.cn

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Vol. 13, Iss. 4 — April 2020

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Images

Figure 1
(a) A typical LWFA structure and transverse-field distributions, with the bubble (green surface), the laser beam (yellow-purple isosurfaces for |E_y| = 1.5), the injected electrons (black dots), the electron density (the x-y plane), and the transverse electric field (E_T, blue arrows) and transverse magnetic field (B_T, red arrows). The amplitude of E_T = (E_y² + E_z²)^1/2 (x = 150 µm plane) is projected onto the x = 140 µm plane. (b) Electron trajectories (solid lines) and spin orientations (arrows) during injection with ϕ∈[–π/2, π/2] at injection radius |r_i| = 6.4 µm, with ϕ = 0 marked in blue and the rest in red. The polarization (average spin components in mesh grids) distributions in the transverse phase space (p_y-p_z) [(c)–(e), respectively] along the x, y, and z axes at 800 fs. The results are collected for simulation parameters a = 2.5, α = 4, and n₀ = 10¹⁸ cm⁻³ and initial electron spins are set along the z axis. The cross-shaped area defined by the phase angle Δϕ_p in (e) represents the high-polarization region.
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Figure 2
Number density in the y-z plane (a) and ϕ−ϕ_p (b) of all injected electrons. The black arrows in (a) denote transverse momentum-vector directions for 1000 randomly selected electrons. (a)–(c) The particle densities in the ϕ_p-s_i space, where i = x (c), i = y (d), and i = z (e). The average spin (polarization) of each is shown from the theoretical analysis (dashed blue line) and the simulations (solid black line, calculated from integrating the density along the s_i axis). The simulation parameters are the same as in Fig. 1.
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Figure 3
(a) A spin filter using the X-shaped slit to produce polarized electron beams, where the slit selects electrons within the region [–Δϕ_p/2, Δϕ_p/2]. (b) Beam polarization along the z axis ( $ζ_{z}$ ) as a function of the selecting angle Δϕ_p for LWFA (solid red line and cyan squares) and PWFA (dotted blue line and cyan circles). The simulation results are obtained with the same parameters as in Fig. 2. (c) $ζ_{z}$ as a function of the normalized parameter ψ from simulations for LWFA (cyan squares) and PWFA (cyan circles) with Δϕ_p = π/10, π/5, π/2, and π. The simulations results are given for a = 0.5–5 for LWFA and σ_l = 0.8 $\approx$ 4 µm, σ_r = 1.6 $\approx$ 3.2 µm, and n_b₀ = 1.5×10¹⁹ cm⁻³ for PWFA with α = 4 and n₀ = 10¹⁸ cm⁻³. The theoretical predictions are shown by lines.
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Figure 4
Polarization (statistics along the z axis) distributions in the transverse phase space (p_y-p_z) for (a) ρ₁ = 0.9 and ρ₂ = 0 and (b) ρ₁ = 0.8 and ρ₂ = 0. The polarization along the z axis as a function of (c) ρ₁ and (d) ρ₂ for selecting angles Δϕ_p = π/2 and π/5. The other simulation parameters are the same as in Fig. 1.
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Figure 5
(a) Polarization along the z axis as a function of initial electron temperature. (b) Polarization (blue squares) and selecting charge (red circles) as a function of the transverse size (along the y axis) of the filter L_ty. The polarization as a function of longitudinal thickness (along the x axis) L_tx and drive-beam jitter in the z direction (j_y = 0) (c) and in the y direction (j_z = 0) (d). The target is set 50 cm from the filter. The selecting angle Δϕ = π/2, while the other simulation parameters are the same as in Fig. 1.
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