Oxford Centre for High Energy Density Science (OxCHEDS)

Free-free opacity in warm dense aluminum

High Energy Density Physics 5:3 (2009) 124-131

Authors:

SM Vinko, G Gregori, MP Desjarlais, B Nagler, TJ Whitcher, RW Lee, P Audebert, JS Wark

Abstract:

We present calculations of the free-free opacity of warm, solid-density aluminum at photon energies between the plasma frequency at 15 eV and the L-edge at 73 eV, using both density functional theory combined with molecular dynamics and a semi-analytical model in the RPA framework which includes exciton contributions. As both the ion and electron temperature is increased from room temperature to 10 eV, we see a marked increase in the opacity. The effect is less pronounced if only the electron temperature is allowed to increase, while the lattice remains at room temperature. The physical significance of these increases is discussed in terms of intense light-matter interactions on both femtosecond and picosecond time scales. © 2009 Elsevier B.V. All rights reserved.

Radiation and hot electron temperature measurements of short-pulselaser driven hohlraums

High Energy Density Physics 5:3 (2009) 212-215

Authors:

CRD Brown, SF James, FN Beg, C Constantin, RL Daskalova, R Edwards, RR Freeman, DP Higginson, JW Morton, C Niemann, D Riley, BR Thomas, L van Woerkom, DJ Hoarty, SJ Rose, G Gregori

Abstract:

We have performed measurements of the radiation and the hot electron temperature in sub-millimetre size hohlraums driven by a high intensity short-pulse laser. The results indicate that radiation temperatures ∼80 eV can be obtained with ∼20 J of laser energy delivered on target. Radiation-hydrodynamics simulations indicate an absorption into thermal X-rays of ≲1-2%, with peak temperatures similar to those measured experimentally. Crown Copyright © 2009.

Opacity calculations on plasmas with open M and N shell configurations

High Energy Density Physics Elsevier 5:3 (2009) 216-218

Authors:

JA Gaffney, SJ Rose

Radiation and hot electron temperature measurements of short-pulselaser driven hohlraums

High Energy Density Physics Elsevier 5:3 (2009) 212-215

Authors:

CRD Brown, SF James, FN Beg, C Constantin, RL Daskalova, R Edwards, RR Freeman, DP Higginson, JW Morton, C Niemann, D Riley, BR Thomas, L van Woerkom, DJ Hoarty, SJ Rose, G Gregori

Mechanisms of electron injection into laser wakefields by a weak counter-propagating pulse

European Physical Journal: Special Topics 175:1 (2009) 49-55

Authors:

ZM Sheng, WM Wang, R Trines, P Norreys, M Chen, J Zhang

Abstract:

Numerical studies are conducted on the electron injection into the first acceleration bucket of a laser wakefield by a weak counter-propagating laser pulse. It is shown that there are two injection mechanisms involved during the colliding laser interaction, the collective injection and stochastic injection. They are caused by the time-averaged ponderomotive force push and stochastic acceleration in the interfering fields, respectively. The threshold amplitude of the injection laser pulse is estimated for the occurrence of electron injection, which is close to that for stochastic acceleration and depends weakly upon the plasma density. The trapping of a large number of injection electrons can result in significant decay of the laser wakefield behind the first wave bucket. © EDP Sciences and Springer 2009.