Abstract
Accelerating particles to high energies in plasma wakefields is considered to be a promising technique with good energy efficiency and high gradient. While important progress has been made in plasma-based electron acceleration, positron acceleration in plasma has been scarcely studied and a fully self-consistent and optimal scenario has not yet been identified. For high energy physics applications where an electron-positron collider would be desired, the ability to accelerate positrons in plasma wakefields is, however, paramount. Here we show that the preservation of beam quality can be compromised in a plasma wakefield loaded with a positron beam, and a tradeoff between energy efficiency and beam quality needs to be found. For electron beams driving linear plasma wakefields, we have found that despite the transversely nonlinear focusing force induced by positron beam loading, the bunch quickly evolves toward an equilibrium distribution with limited emittance growth. Particle-in-cell simulations show that for $\ensuremath{\mu}\mathrm{m}$-scale normalized emittance, the growth of uncorrelated energy spread sets an important limit. Our results demonstrate that the linear or moderately nonlinear regimes with Gaussian drivers provide a good tradeoff, achieving simultaneously energy-transfer efficiencies exceeding 30% and uncorrelated energy spread below 1%, while donut-shaped drivers in the nonlinear regime are more appropriate to accelerate high-charge bunches at higher gradients, at the cost of a degraded tradeoff between efficiency and beam quality.
Highlights
Particle accelerators based on radio-frequency technology are being used in a very broad range of applications, from free-electron lasers or medicine to particle colliders for highenergy physics
Our results show the importance of beam loading in plasma-based positron acceleration, whose properties differ significantly from beam loading for electron acceleration in the blowout regime
Beam loading is a prerequisite for good energy-transfer efficiency, which is highly desirable for a high energy physics application
Summary
Particle accelerators based on radio-frequency technology are being used in a very broad range of applications, from free-electron lasers or medicine to particle colliders for highenergy physics. Apart from the hollow plasma channel accelerator, methods to accelerate positrons in plasma typically have in common the presence of an excess of plasma electrons within the accelerated positron bunch Such plasma wakefields can be used to accelerate low-charge bunches while preserving their quality, for example with weak beam loading in the linear regime [36], but the energy efficiency with weak beam loading is too low to be of interest for a collider application. When increasing positron beam charge and energy efficiency, positron beam loading becomes the key challenge because of the quick response of the plasma electrons to the positron load This quick response can lead to a transversely nonlinear focusing force that can potentially drive emittance growth [37], as well as a transversely nonuniform accelerating field that can induce growth in uncorrelated energy spread.
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