Abstract
We use particle-in-cell (PIC) simulations to study the effects of variations of the incoming 400 GeV proton bunch parameters on the amplitude and phase of the wakefields resulting from a seeded self-modulation (SSM) process. We find that these effects are largest during the growth of the SSM, i.e. over the first five to six meters of plasma with an electron density of $7 \times10^{14}$ cm$^{-3}$. However, for variations of any single parameter by $\pm$5%, effects after the SSM saturation point are small. In particular, the phase variations correspond to much less than a quarter wakefield period, making deterministic injection of electrons (or positrons) into the accelerating and focusing phase of the wakefields in principle possible. We use the wakefields from the simulations and a simple test electron model to estimate the same effects on the maximum final energies of electrons injected along the plasma, which are found to be below the initial variations of $\pm$5%. This analysis includes the dephasing of the electrons with respect to the wakefields that is expected during the growth of the SSM. Based on a PIC simulation, we also determine the injection position along the bunch and along the plasma leading to the largest energy gain. For the parameters taken here (ratio of peak beam density to plasma density $n_{b0}/n_0 \approx 0.003$), we find that the optimum position along the proton bunch is at $\xi \approx -1.5 \; \sigma_{zb}$, and that the optimal range for injection along the plasma (for a highest final energy of $\sim$1.6 GeV after 10 m) is 5-6 m.
Highlights
For the parameters taken here, we find that the optimum position along the proton bunch is at ξ ≈ −1.5σzb, and that the optimal range for injection along the plasma is 5–6 m
The AWAKE experiment intends to demonstrate the concept of proton-driven plasma wakefield acceleration using 400 GeV proton bunches supplied by the Super Proton Synchrotron (SPS) at CERN to accelerate externally injected electrons [1]
We found that the parameter variations we considered (Æ5% and Æ15 ps) essentially lead to differences in wakefield amplitude and phase only in the growth region of the seeded selfmodulation (SSM) along the plasma (z < 4 m in this case)
Summary
The AWAKE experiment intends to demonstrate the concept of proton-driven plasma wakefield acceleration using 400 GeV proton bunches supplied by the Super Proton Synchrotron (SPS) at CERN to accelerate externally injected electrons [1]. In order to drive the wakefields effectively, the length of the driver should be of the order of λpe This is not the case in AWAKE, where the bunches delivered by the SPS are considerably longer (6–12 cm) than the plasma wavelengths in the adjustable density range (∼1–3 mm for ð1–10Þ × 1014 cm−3). This causes the long proton bunch to undergo the self-modulation instability (SMI) [9], whereby the bunch is progressively modulated into a train of shorter bunches, with lengths and separation distances of the order of λpe, due to periodic transversely focusing and defocusing fields. We assume in this work that the seed for the self-modulation process is large enough to prevent the growth of the hose instability [9,19]
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