Density functional theory calculations of continuum lowering in strongly coupled plasmas.
Nature communications 5 (2014) 3533-3533
Abstract:
An accurate description of the ionization potential depression of ions in plasmas due to their interaction with the environment is a fundamental problem in plasma physics, playing a key role in determining the ionization balance, charge state distribution, opacity and plasma equation of state. Here we present a method to study the structure and position of the continuum of highly ionized dense plasmas using finite-temperature density functional theory in combination with excited-state projector augmented-wave potentials. The method is applied to aluminium plasmas created by intense X-ray irradiation, and shows excellent agreement with recently obtained experimental results. We find that the continuum lowering for ions in dense plasmas at intermediate temperatures is larger than predicted by standard plasma models and explain this effect through the electronic structure of the valence states in these strong-coupling conditions.Molecular dynamics simulations of shock-induced plasticity in tantalum
High Energy Density Physics Elsevier 10 (2014) 9-15
Single photon energy dispersive x-ray diffraction.
The Review of scientific instruments 85:3 (2014) 033906
Abstract:
With the pressure range accessible to laser driven compression experiments on solid material rising rapidly, new challenges in the diagnosis of samples in harsh laser environments are emerging. When driving to TPa pressures (conditions highly relevant to planetary interiors), traditional x-ray diffraction techniques are plagued by increased sources of background and noise, as well as a potential reduction in signal. In this paper we present a new diffraction diagnostic designed to record x-ray diffraction in low signal-to-noise environments. By utilising single photon counting techniques we demonstrate the ability to record diffraction patterns on nanosecond timescales, and subsequently separate, photon-by-photon, signal from background. In doing this, we mitigate many of the issues surrounding the use of high intensity lasers to drive samples to extremes of pressure, allowing for structural information to be obtained in a regime which is currently largely unexplored.Molecular dynamics simulations of shock-compressed single-crystal silicon
Physical Review B American Physical Society (APS) 89:6 (2014) 064104
Imaging Lattice dynamics in individual nanocrystals
Optics InfoBase Conference Papers (2014)