Laser-plasma accelerator group

Reconstructing nonlinear plasma wakefields using a generalized temporally encoded spectral shifting analysis

Physical Review Accelerators and Beams American Physical Society 21 (2018) 103501

Authors:

Christopher Arran, NH Matlis, Roman Walczak, Simon M Hooker

Abstract:

We generalize the temporally encoded spectral shifting (TESS) analysis for measuring plasma wakefields using spectral interferometry to dissimilar probe pulses of arbitrary spectral profile and to measuring nonlinear wakefields. We demonstrate that the Gaussian approximation used up until now results in a substantial miscalculation of the wakefield amplitude, by a factor of up to two. A method to accurately measure higher amplitude quasilinear and nonlinear wakefields is suggested, using an extension to the TESS procedure, and we place some limits on its accuracy in these regimes. These extensions and improvements to the analysis demonstrate its potential for rapid and accurate on-shot diagnosis of plasma wakefields, even at low plasma densities.

Reconstructing nonlinear plasma wakefields using a generalized temporally encoded spectral shifting analysis

Physical Review Accelerators and Beams 21 (2018) 103501-103501

Authors:

C Arran, NH Matlis, R Walczak, SM Hooker

Abstract:

We generalize the temporally encoded spectral shifting (TESS) analysis for measuring plasma wakefields using spectral interferometry to dissimilar probe pulses of arbitrary spectral profile and to measuring nonlinear wakefields. We demonstrate that the Gaussian approximation used up until now results in a substantial miscalculation of the wakefield amplitude, by a factor of up to two. A method to accurately measure higher amplitude quasilinear and nonlinear wakefields is suggested, using an extension to the TESS procedure, and we place some limits on its accuracy in these regimes. These extensions and improvements to the analysis demonstrate its potential for rapid and accurate on-shot diagnosis of plasma wakefields, even at low plasma densities.

Emittance Preservation in an Aberration-Free Active Plasma Lens

(2018)

Authors:

CA Lindstrøm, E Adli, G Boyle, R Corsini, AE Dyson, W Farabolini, SM Hooker, M Meisel, J Osterhoff, J-H Röckemann, L Schaper, KN Sjobak

Laser wakefield acceleration with mid-IR laser pulses

Optics Letters The Optical Society 43:5 (2018) 1131-1131

Authors:

D Woodbury, L Feder, V Shumakova, C Gollner, R Schwartz, B Miao, F Salehi, A Korolov, A Pugžlys, A Baltuška, Hm Milchberg

Abstract:

We report on, to the best of our knowledge, the first results of laser plasma wakefield acceleration driven by ultrashort mid-infrared (IR) laser pulses (𝜆=3.9 μm, 100 fs, 0.25 TW), which enable near- and above-critical density interactions with moderate-density gas jets. Relativistic electron acceleration up to ∼12 MeV occurs when the jet width exceeds the threshold scale length for relativistic self-focusing. We present scaling trends in the accelerated beam profiles, charge, and spectra, which are supported by particle-in-cell simulations and time-resolved images of the interaction. For similarly scaled conditions, we observe significant increases in the accelerated charge, compared to previous experiments with near-infrared (𝜆=800 nm) pulses.

Layout considerations for a future electron plasma research accelerator facility EuPRAXIA

Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment Elsevier 909 (2018) 111-113

Authors:

PA Walker, RW Assmann, R Brinkmann, E Chiadroni, U Dorda, M Ferrario, D Kocon, B Marchetti, L Pribyl, A Specka, Roman Walczak

Abstract:

The Horizon 2020 Project EuPRAXIA (“European Plasma Research Accelerator with eXcellence In Applications”) is preparing a conceptual design for a highly compact and cost-effective European facility with multi-GeV electron beams using plasma as the acceleration medium. The design includes two user areas: one for FEL science and one for High Energy Physics (HEP) detector development and other pilot applications. The accelerator facility will be based on a laser and/or a beam driven plasma acceleration approach. This contribution introduces layout considerations of the future plasma accelerator facilities in the context of EuPRAXIA. It compares conventional and novel plasma accelerator facility requirements and presents potential layouts for the future site. Together with performance analysis, cost effectiveness, and targeted user cases of the individual configurations, such layout studies will later enable a ranking of potential configurations. Based on this information the optimal combination of technologies will be defined for the 2019 conceptual design report of the EuPRAXIA facility.