Oxford Centre for High Energy Density Science (OxCHEDS)

Characteristics of betatron radiation from direct-laser accelerated electrons

Physical Review E - Statistical Physics, Plasmas, Fluids, and Related Interdisciplinary Topics American Physical Society 93:6 (2016) 063203

Authors:

Tai W Huang, Alex PL Robinson, Chong-Tan Zhou, Bin Qiao, Baolin Liu, Ruan Shang-Chen, He Xian-Tu, Peter A Norreys

Abstract:

Betatron radiation from direct-laser accelerated electrons is characterized analytically and numerically. It is shown here that the electron dynamics is strongly dependent on a self-similar parameter S(≡ne/nca0). Both the electron transverse momentum and energy are proportional to the normalized amplitude of laser field (a0) for a fixed value of S. As a result, the total number of radiated photons scales as a2/0/√S and the energy conversion efficiency of photons from the accelerated electrons scales as a3/0/S. The particle-in-cell simulations agree well with the analytical scalings. It is suggested that a tunable high-energy and high-flux radiation source can be achieved by exploiting this regime.

Characteristics of betatron radiation from direct-laser-accelerated electrons

Physical Review E American Physical Society 93 (2016) 063203

Authors:

Peter Norreys, TW Huang, APL Robinson, CT Zhou, B Qiao, B Liu, SC Ruan, XT He

Abstract:

Betatron radiation from direct-laser-accelerated electrons is characterized analytically and numerically. It is shown here that the electron dynamics is strongly dependent on a self-similar parameter S ( ≡ n e n c a 0 ). Both the electron transverse momentum and energy are proportional to the normalized amplitude of laser field ( a 0 )fora fixed value of S . As a result, the total number of radiated photons scales as a 2 0 / √ S and the energy conversion efficiency of photons from the accelerated electrons scales as a 3 0 /S . The particle-in-cell simulations agree well with the analytical scalings. It is suggested that a tunable high-energy and high-flux radiation source can be achieved by exploiting this regime.

Effect of Preplasma on Double Pulse Irradiation of Targets for Proton Acceleration

Institute of Electrical and Electronics Engineers (IEEE) (2016) 1-1

Authors:

Shaun Kerr, Mianzhen Z Mo, Raj Masud, Xiaolin Jin, Laila Manzoor, Henry F Tiedje, Ying Tsui, Robert Fedosejevs, Anthony Link, Pray Patel, Harry S McLean, Andy Hazi, Hui Chen, Luke Ceurvorst, Peter Norreys

Measurements of continuum lowering in solid-density plasmas created from elements and compounds

Nature Communications Nature Publishing Group 7:1 (2016) 11713

Authors:

Orlando Ciricosta, Sam M Vinko, Benjamin Barbrel, David S Rackstraw, Thomas R Preston, Tomas Burian, Jaromir Chalupsky, Byoung I Cho, Hyun-Kyung Chung, Georgi L Dakovski, Kyle Engelhorn, Vera Hajkova, Philip Heimann, Michael Holmes, Libor Juha, Jacek Krzywinski, Richard W Lee, Sven Toleikis, Joshua J Turner, Ulf Zastrau, Justin S Wark

Abstract:

The effect of a dense plasma environment on the energy levels of an embedded ion is usually described in terms of the lowering of its continuum level. For strongly coupled plasmas, the phenomenon is intimately related to the equation of state; hence, an accurate treatment is crucial for most astrophysical and inertial-fusion applications, where the case of plasma mixtures is of particular interest. Here we present an experiment showing that the standard density-dependent analytical models are inadequate to describe solid-density plasmas at the temperatures studied, where the reduction of the binding energies for a given species is unaffected by the different plasma environment (ion density) in either the element or compounds of that species, and can be accurately estimated by calculations only involving the energy levels of an isolated neutral atom. The results have implications for the standard approaches to the equation of state calculations.

Mitigating the hosing instability in relativistic laser-plasma interactions

New Journal of Physics IOP Publishing (2016)

Authors:

Peter Norreys, L Ceurvorst, N Ratan, MC Levy, MF Kasim, J Sadler, RHH Scott, RMGM Trines, TW Huang, M Skramic, M Vranic, LO Silva

Abstract:

A new physical model of the hosing instability that includes relativistic laser pulses and moderate densities is presented and derives the density dependence of the hosing equation. This is tested against two-dimensional particle-in-cell simulations. These simulations further examine the feasibility of using multiple pulses to mitigate the hosing instability in a Nd:glass-type parameter space. An examination of the effects of planar versus cylindrical exponential density gradients on the hosing instability is also presented. The results show that strongly relativistic pulses and more planar geometries are capable of mitigating the hosing instability which is in line with the predictions of the physical model.