Polarized Laser-WakeField-Accelerated Kiloampere Electron Beams

Wen, Meng; Tamburini, Matteo; Keitel, Christoph H.

doi:10.1103/physrevlett.122.214801

Cited by 78 publications

(84 citation statements)

References 51 publications

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“…injection time for Δt∼π|r i −r 0 |/〈β x 〉∼4π|r i −r 0 |/c LG case and Δt∼2πr i /c Gaussian case, which is close to previous studies where considering trapped electrons as a whole with Δt≈4a 1/2 λ p /πc [30,53,54]. Assuming the injection density is homogenous among whole injection region, the whole polarization after injection is given as:…”

Section: Results and Theoretical Analysissupporting

confidence: 79%

“…As shown below, spin depolarization mainly happens in the injection phase, which is in line with previous studies [29]. Recently, a method is proposed to mitigate this issue by fine tuning the focal position of the Gaussian laser beam to weaken the electron injection [30]. Here we propose that compared to Gaussian lasers, vortex laser beams are capable of creating a unique topology in LWFA that significantly suppresses the beam depolarization without sacrifice of the injected electron charge.…”

Section: Introductionsupporting

confidence: 80%

“…The vortex beam produces a donut-shaped electron bunch in the vicinity of r 0 ±!r/2, as compared to a cylinder-like beam of radius !r for the Gaussian driver, corresponding to a cross-section area of 2πr 0 !r and π!r 2 , respectively. For a simple estimation, we use !r∼a 1/2 λ p (x p )/π∼4 μm [30,[48][49][50] as the bunch radius of the trapped electrons and r 0 =w 0 / 2 ≈7 μm as the center of the trapped region for the LG case [48,49]. Accordingly, the peak-current ratio between the LG and the Gaussian case is about 2r 0 /!r∼3.5, a factor that is well reproduced in simulations.…”

Section: Results and Theoretical Analysissupporting

confidence: 56%

“…similar to the one used in [30], for better comparison. Here Θ(x) is the step function, ξ=x−x 0 , x 0 =20 μm, L=16 μm, ratio between the peak density of the ramp and the background density κ=n p /n 0 =4, n p is the peak density while n 0 =10 18 cm −3 is the background density, respectively.…”

Section: Spin Dynamics and Simulation Parametersmentioning

confidence: 99%

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Polarized electron-beam acceleration driven by vortex laser pulses

Geng

et al. 2019

New J. Phys.

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We propose a new approach based on an all-optical set-up for generating relativistic polarized electron beams via vortex Laguerre-Gaussian (LG) laser-driven wakefield acceleration. Using a pre-polarized gas target, we find that the topology of the vortex wakefield resolves the depolarization issue of the injected electrons. In full three-dimensional particle-in-cell simulations, incorporating the spin dynamics via the Thomas-Bargmann Michel Telegdi equation, the LG laser preserves the electron spin polarization by more than 80% while assuring efficient electron injection. The method releases the limit on beam flux for polarized electron acceleration and promises more than an order of magnitude boost in peak flux, as compared to Gaussian beams. These results suggest a promising table-top method to produce energetic polarized electron beams.

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Section: Results and Theoretical Analysissupporting

confidence: 79%

Section: Introductionsupporting

confidence: 80%

Section: Results and Theoretical Analysissupporting

confidence: 56%

Section: Spin Dynamics and Simulation Parametersmentioning

confidence: 99%

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Polarized electron-beam acceleration driven by vortex laser pulses

Geng

et al. 2019

New J. Phys.

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“…Such field distributions are also seen in our simulations ( Fig.1 (a)). As already stated in previous works [27][28][29]45], the spin is preserved during steady acceleration but precesses dramatically during the injection phase. That is why we focus on the spin dynamics during injection, where typically one has γ<<1/a e [42,46] and the second term of Eq.…”

Section: Resultssupporting

confidence: 67%

Spin Filter for Polarized Electron Acceleration in Plasma Wakefields

Geng

et al. 2020

Phys. Rev. Applied

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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 to identify all electron-beam subsets with low-polarization and to filter them out by an X-shaped slit placed right 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 anti-parallel 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, e.g. <1kA in Ref.[27]. This limitation is removed by employing the proposed filter mechanism. The robust of the method is discussed that contains drive beam fluctuations, jitters, the thickness of the filter and initial temperature.This idea marks an efficient and simple strategy to generate energetic polarized electron beams based on wakefield acceleration.

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Production of polarized particle beams via ultraintense laser pulses

Sun

Zhao

Xue

et al. 2022

Rev. Mod. Plasma Phys.

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High-energy spin-polarized electron, positron, and -photon beams have many significant applications in the study of material properties, nuclear structure, particle physics, and high-energy astrophysics. Thus, efficient production of such polarized beams attracts a broad spectrum of research interests. This is driven mainly by the rapid advancements in ultrashort and ultraintense laser technology. Currently, available laser pulses can achieve peak intensities in the range of 10 22 -10 23 Wcm −2 , with pulse durations of tens of femtoseconds. The dynamics of particles in laser fields of the available intensities is dominated by quantum electrodynamics (QED) and the interaction mechanisms have reached regimes spanned by nonlinear multiphoton absorption (strong-field QED processes). In strong-field QED processes, the scattering cross-sections obviously depend on the spin and polarization of the particles, and the spin-dependent photon emission and the radiation-reaction effects can be utilized to produce the polarized particles. An ultraintense laser-driven polarized particle source possesses the advantages of high brilliance and compactness, which could open the way for the unexplored aspects in a range of researches. In this work, we briefly review the seminal conclusions from the study of the polarization effects in strong-field QED processes, as well as the progress made by recent proposals for production of the polarized particles by laser-beam or laser-plasma interactions.

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Polarized Laser-WakeField-Accelerated Kiloampere Electron Beams

Cited by 78 publications

References 51 publications

Polarized electron-beam acceleration driven by vortex laser pulses

Polarized electron-beam acceleration driven by vortex laser pulses

Spin Filter for Polarized Electron Acceleration in Plasma Wakefields

Production of polarized particle beams via ultraintense laser pulses

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