The AWAKE (Advanced WAKEfield Experiment) facility at CERN is a proof-of-principle experiment, which investigates wakefield plasma acceleration using a proton bunch as a driver, a world-wide first. It aims to accelerate a low-energy witness bunch of electrons from 15 to 20 MeV to several GeV over a short distance (10 m) by creating a high acceleration gradient of several GV/m. Particle accelerators currently in use, like CERN's LHC, use standard or superconductive RF-cavities for acceleration, but they are limited to an acceleration gradient in the order of 100 MV/m.

Circular accelerator machines are not efficient for transporting electrons at high energy due to the large energy loss in synchrotron radiation. Linear accelerators do not have this issue and are therefore better suited for accelerating and transporting electrons at high energies.

AWAKE's high acceleration gradient will allow the construction of a new generation of shorter and less expensive high energy accelerators, representing a big step in the particle accelerators technology, especially for linear electron accelerators.

A plasma consists of positively charged ions and negatively charged free electrons, while remaining macroscopically neutral. If a strong electric field is applied, ions and electrons can be spatially separated. A local electric field is thereby created, thus a charged particle entering a such plasma can be accelerated.

When the driver, the positively charged proton bunch, penetrates the plasma, it attracts the negatively charged plasma electrons, they overshoot and start to oscillate, creating a wakefield. The interaction between the wakefield and a charged particle injected behind the proton can be interpreted as the same as the one between a surfer and a wave. The latter will transfer its energy to the surfer who will thus be accelerated. The wakefield consists of decelerating and accelerating phase, as well as focusing and defocusing phase. The injection position of the electron bunch in the wakefield is thus crucial, since only a fraction (1/4th) of the wakefield is both focused and accelerated, which is needed for the trapping and the acceleration of the electrons. AWAKE is the first plasma wakefield experiment using a bunch of protons as a driver. Protons, as for example the protons that form the CERN Super Proton Synchrotron (SPS), can carry a large amount of energy (~ 400 GeV). Therefore, they can produce wakefields in a plasma for much longer distances than a laser pulse or electron bunch as a driver due to energy depletion.

A plasma can be seen as an ensemble of oscillators with a frequency of the plasma frequency ω_p²=4n_ee²/εm_e, with n_e the plasma electron density, m_e the electron mass and e the elementary charge. To excite those oscillators resonantly, the driver must contain a Fourier component close to the plasma frequency ω_p. Moreover, the length of the drive bunch should be close to the plasma wavelength λ_p (=2πc/ω_p with c is the speed of light). For AWAKE like density (n_e ≈ 1•10¹⁵ cm⁻³) this corresponds to approximately λ_p ≈ 1 mm. The length of currently available proton bunches though exceeds this value significantly. AWAKE profits form the seeded self-modulation (SSM) of the proton bunch travelling through the plasma, which divides the long proton bunch into shorts micro-bunches with the length of the plasma wavelength that can drive the wakefield resonantly.

The AWAKE experiment is installed at CERN, in the former CERN Neutrinos to Gran Sasso (CNGS) facility. This site was selected for its underground location, and it was specifically designed for the use of high-energy proton beams without any significant radiation issue.

The proton bunches for AWAKE are extracted from the CERN SPS and are transported through an ~800-meter beam-line to the 10-meter long vapor source of AWAKE. The electron witness bunches are injected behind the proton bunch. To detect acceleration of the injected electrons, a dipole magnet is installed after the vapor, bending their path. The larger the electron's energy, the smaller curvature of its path. A scintillation screen then detects accelerated electrons.