Prof Peter Norreys FInstP;

Simulations of efficient Raman amplification into the multipetawatt regime

Nature Physics 7:1 (2011) 87-92

Authors:

RMGM Trines, F Fiúza, R Bingham, RA Fonseca, LO Silva, RA Cairns, PA Norreys

Abstract:

Contemporary high-power laser systems make use of solid-state laser technology to reach petawatt pulse powers. The breakdown threshold for optical components in these systems, however, demands metre-scale beams. Raman amplification of laser beams promises a breakthrough by the use of much smaller amplifying media, that is, millimetre-diameter plasmas, but so far only 60 GW peak powers have been obtained in the laboratory, far short of the desired multipetawatt regime. Here we show, through the first large-scale multidimensional particle-in-cell simulations of this process, that multipetawatt peak powers can be reached, but only in a narrow parameter window dictated by the growth of plasma instabilities. Raman amplification promises reduced cost and complexity of intense lasers, enabling much greater access to higher-intensity regimes for scientific and industrial applications. Furthermore, we show that this process scales to short wavelengths, enabling compression of X-ray free-electron laser pulses to attosecond duration. © 2011 Macmillan Publishers Limited. All rights reserved.

A Vlasov-Fokker-Planck code for high energy density physics

JOURNAL OF COMPUTATIONAL PHYSICS 230:17 (2011) 6475-6494

Authors:

M Tzoufras, AR Bell, PA Norreys, FS Tsung

The 10PW OPCPA Vulcan Laser Upgrade

Optica Publishing Group (2011) hthe2

Authors:

Andrey Lyachev, Oleg Chekhlov, John Collier, Rob Clarke, Marco Galimberti, Cristina Hernandez-Gomez, Pavel Matousek, Ian Musgrave, David Neely, Peter Norreys, Ian Ross, Yunxin Tang, Trevor Winstone, Brian Wyborn

Controlling fast electron beam divergence using two laser pulses

(2010)

Authors:

RHH Scott, C Beaucourt, H-P Schlenvoigt, K Markey, KL Lancaster, CP Ridgers, CM Brenner, J Pasley, RJ Gray, IO Musgrave, APL Robinson, K Li, MM Notley, JR Davies, SD Baton, JJ Santos, J-L Feugeas, Ph Nicolaï, G Malka, VT Tikhonchuk, P McKenna, D Neely, SJ Rose, PA Norreys

Applications of the wave kinetic approach: From laser wakefields to drift wave turbulence

Journal of Plasma Physics 76:6 (2010) 903-914

Authors:

RMGM Trines, R Bingham, LO Silva, JT Mendonça, PK Shukla, CD Murphy, MW Dunlop, JA Davies, R Bamford, A Vaivads, PA Norreys

Abstract:

Nonlinear wave-driven processes in plasmas are normally described by either a monochromatic pump wave that couples to other monochromatic waves, or as a random phase wave coupling to other random phase waves. An alternative approach involves a random or broadband pump coupling to monochromatic and/or coherent structures in the plasma. This approach can be implemented through the wave-kinetic model. In this model, the incoming pump wave is described by either a bunch (for coherent waves) or a sea (for random phase waves) of quasi-particles. This approach has been applied to both photon acceleration in laser wakefields and drift wave turbulence in magnetized plasma edge configurations. Numerical simulations have been compared to experiments, varying from photon acceleration to drift mode-zonal flow turbulence, and good qualitative correspondences have been found in all cases. © 2010 Cambridge University Press.