Richard D'Arcy

Recovery time of a plasma-wakefield accelerator

Nature Springer Nature 603:7899 (2022) 58-62

Authors:

R D’Arcy, James Chappell, J Beinortaite, S Diederichs, G Boyle, B Foster, Mj Garland, P Gonzalez Caminal, Ca Lindstrøm, G Loisch, S Schreiber, S Schröder, Rj Shalloo, M Thévenet, S Wesch, M Wing, J Osterhoff

Abstract:

The interaction of intense particle bunches with plasma can give rise to plasma wakes capable of sustaining gigavolt-per-metre electric fields, which are orders of magnitude higher than provided by state-of-the-art radio-frequency technology. Plasma wakefields can, therefore, strongly accelerate charged particles and offer the opportunity to reach higher particle energies with smaller and hence more widely available accelerator facilities. However, the luminosity and brilliance demands of high-energy physics and photon science require particle bunches to be accelerated at repetition rates of thousands or even millions per second, which are orders of magnitude higher than demonstrated with plasma-wakefield technology. Here we investigate the upper limit on repetition rates of beam-driven plasma accelerators by measuring the time it takes for the plasma to recover to its initial state after perturbation by a wakefield. The many-nanosecond-level recovery time measured establishes the in-principle attainability of megahertz rates of acceleration in plasmas. The experimental signatures of the perturbation are well described by simulations of a temporally evolving parabolic ion channel, transferring energy from the collapsing wake to the surrounding media. This result establishes that plasma-wakefield modules could be developed as feasible high-repetition-rate energy boosters at current and future particle-physics and photon-science facilities.

A hybrid, asymmetric, linear Higgs factory based on plasma-wakefield and radio-frequency acceleration

New Journal of Physics IOP Publishing 25:9 (2023) 093037

Authors:

B Foster, R D’Arcy, CA Lindstrøm

FLASHForward: plasma wakefield accelerator science for high-average-power applications.

Philosophical Transactions of the Royal Society A Royal Society 377:2151 (2019) Article:20180392

Authors:

R D'Arcy, A Aschikhin, S Bohlen, G Boyle, T Brümmer, J Chappell, S Diederichs, Brian Foster, MJ Garland, L Goldberg, P Gonzalez, S Karstensen, A Knetsch, P Kuang, V Libov, K Ludwig, A Martinez De La Ossa, F Marutzky, M Meisel, TJ Mehrling, P Niknejadi, K Põder, P Pourmoussavi, M Quast, J-H Röckemann, L Schaper, B Schmidt, S Schröder, J-P Schwinkendorf, B Sheeran, G Tauscher, S Wesch, M Wing, P Winkler, M Zeng, J Osterhoff

Abstract:

The FLASHForward experimental facility is a high-performance test-bed for precision plasma wakefield research, aiming to accelerate high-quality electron beams to GeV-levels in a few centimetres of ionized gas. The plasma is created by ionizing gas in a gas cell either by a high-voltage discharge or a high-intensity laser pulse. The electrons to be accelerated will either be injected internally from the plasma background or externally from the FLASH superconducting RF front end. In both cases, the wakefield will be driven by electron beams provided by the FLASH gun and linac modules operating with a 10 Hz macro-pulse structure, generating 1.25 GeV, 1 nC electron bunches at up to 3 MHz micro-pulse repetition rates. At full capacity, this FLASH bunch-train structure corresponds to 30 kW of average power, orders of magnitude higher than drivers available to other state-of-the-art LWFA and PWFA experiments. This high-power functionality means FLASHForward is the only plasma wakefield facility in the world with the immediate capability to develop, explore and benchmark high-average-power plasma wakefield research essential for next-generation facilities. The operational parameters and technical highlights of the experiment are discussed, as well as the scientific goals and high-average-power outlook.

Tunable Plasma-Based Energy Dechirper

Physical Review Letters American Physical Society (APS) 122:3 (2019) 034801

Authors:

R D'Arcy, S Wesch, A Aschikhin, S Bohlen, C Behrens, MJ Garland, L Goldberg, P Gonzalez, A Knetsch, V Libov, A Martinez de la Ossa, M Meisel, TJ Mehrling, P Niknejadi, K Poder, J-H Röckemann, L Schaper, B Schmidt, S Schröder, C Palmer, J-P Schwinkendorf, B Sheeran, MJV Streeter, G Tauscher, V Wacker, J Osterhoff

Characterization of discharge capillaries via benchmarked hydrodynamic plasma simulations

Physical Review Research American Physical Society (APS) 7:4 (2025) 043193

Authors:

SM Mewes, GJ Boyle, R D’Arcy, JM Garland, M Huck, H Jones, G Loisch, AR Maier, J Osterhoff, T Parikh, S Wesch, JC Wood, M Thévenet

Abstract:

Plasma accelerators utilize strong electric fields in plasma waves to accelerate charged particles, making them a compact alternative to radiofrequency technologies. Discharge capillaries are plasma sources used in plasma accelerator research to provide acceleration targets, or as plasma lenses to capture or focus accelerated beams. They have applications for beam-driven and laser-driven plasma accelerators and can sustain high repetition rates for extended periods of time. Despite these advantages, high-fidelity simulations of discharge capillaries remain challenging due to the range of mechanisms involved and the difficulty to diagnose them in experiments. In this work, we utilize hydrodynamic plasma simulations to examine the discharge process of a plasma cell and discuss implications for future accelerator systems. The simulation model is validated with experimental measurements in a 50-mm-long, 1-mm-wide plasma capillary operating a 12–27 kV discharge at 200–1200 Pa hydrogen pressure. For 20 kV at 870 Pa, the discharge is shown to deposit 178 mJ of energy in the plasma. Potential difficulties with the common density measurement method using H α emission spectroscopy are discussed. This simulation model enables investigations of repeatability, heat flow management, and fine tailoring of the plasma profile with discharges.