Oxford Centre for High Energy Density Science (OxCHEDS)

Analysis of four-wave mixing of high-power lasers for the detection of elastic photon-photon scattering

(2006)

Authors:

J Lundin, M Marklund, E Lundstrom, G Brodin, J Collier, R Bingham, JT Mendonca, P Norreys

High energy electron transport in solids

Journal De Physique. IV : JP 133 (2006) 355-360

Authors:

RB Stephens, RPJ Snavely, Y Aglitskii, KU Akli, F Amiranoff, C Andersen, D Batani, SD Baton, T Cowan, RR Freeman, JS Green, H Habara, T Hall, SP Hatchett, DS Hey, JM Hill, JL Kaae, MH Key, JA King, JA Koch, R Kodama, M Koenig, K Krushelnick, KL Lancaster, AJ MacKinnon, E Martinolli, CD Murphy, M Nakatsutsumi, P Norreys, E Perelli-Cippo, MR Le Gloahec, B Remington, C Rousseaux, JJ Santos, F Scianitti, C Stoeckl, M Tabak, KA Tanaka, W Theobald, R Town, T Yabuuchi, B Zhang

Abstract:

With the addition of recent PW shots, the propagation of short-pulse laser generated electron beams have been studied using laser pulse energies from 30 J to 300 J, generating currents up to ∼15 MA in solid Al:Cu targets. This is ∼5% of the current that will be required in an ignition pulse. To this level, the current appears to simply scale with laser power, the propagation spread not change at all. The resistance of the aluminum does not seem to play a role in the propagation characteristics, though it might in setting the current starting parameters. We do find that at the highest currents parts of these targets reach temperatures high enough to modify the Cu-K2 emission spectrum rendering our Bragg imaging mirrors ineffective; spectrometers will be needed to collect data at these higher temperatures. © EDP Sciences.

Vulcan petawatt-operation and development

Journal De Physique. IV : JP 133 (2006) 555-559

Authors:

C Hernandez-Gomez, PA Brummitt, DJ Canny, RJ Clarke, J Collier, CN Danson, AM Dunne, B Fell, AJ Frackiewicz, S Hancock, S Hawkes, R Heathcote, P Holligan, MHR Hutchinson, A Kidd, WJ Lester, IO Musgrave, D Neely, DR Neville, PA Norreys, DA Pepler, CJ Reason, W Shaikh, TB Winstone, BE Wyborn

Abstract:

Petawatt capability on the Vulcan laser facility has been available to the international plasma physics community for over two years. This has enabled novel experiments to be carried out and new regimes of physics to be explored. During that time, there have been 10 successful user experiments with 89% of shots delivered within the requested energy limits. In the autumn of 2004, pulses with powers of more than a petawatt (1015Watts) were delivered to target with energies greater than 400 J and pulse widths shorter than 500 femtoseconds (10-15) on target. In parallel to the development of ultra-high intensity pulses is a programme to enhance Vulcan's long pulse capabilities. This paper will present an overview of the current capabilities of the Vulcan Petawatt facility and discuss some of the recent technological advances that have enabled the generation of Petawatt pulses. © EDP Sciences.

Efficient coupling of 527 nm laser beam power to a long scalelength plasma

J PHYS IV 133 (2006) 321-324

Authors:

JD Moody, L Divol, SH Glenzer, AJ MacKinnon, DH Froula, G Gregori, WL Kruer, NB Meezan, LJ Suter, EA Williams, R Bahr, W Seka

Abstract:

We experimentally demonstrate that application of laser smoothing schemes including smoothing by spectral dispersion (SSD) and polarization smoothing (PS) increases the intensity range for efficient coupling of frequency doubled (527 nm) laser light to a long scalelength plasma with n(e)/n(cr) = 0.14 and T-e = 2 keV.

Overview of recent progress in US fast ignition research

J PHYS IV 133 (2006) 95-100

Authors:

RR Freeman, K Akli, F Beg, R Betti, S Chen, DJ Clark, PM Gu, G Gregori, SP Hatchett, D Hey, K Highbarger, JM Hill, N Izumi, M Key, JA King, JA Koch, B Lasinki, B Langdon, AJ MacKinnon, D Meyerhofer, N Patel, P Patel, J Pasley, HS Park, C Ren, RA Snavely, RB Stephens, C Stoeckl, M Tabak, R Town, L Van Woerkom, R Weber, SC Wilks, BB Zhang

Abstract:

The Fast Ignition Program in the United States has enjoyed increased funding in various forms from the Office of Fusion Energy Sciences of the Department of Energy. The program encompasses experiments on large laser facilities at various world-wide locations, and benefits enormously from collaborations with many international scientists. The program includes exploratory work in cone-target design and implosion dynamics, high electron current transport measurements in normal density materials, development of diagnostics for heating measurements, generation of protons from shaped targets, theoretical work on high gain target designs, and extensive modeling development using PIC and hybrid codes.