Professor Justin Wark

Opacity effects in a solid-density aluminium plasma created by photo-excitation with an X-ray laser

High Energy Density Physics Elsevier 11 (2014) 59-69

Authors:

DS Rackstraw, SM Vinko, O Ciricosta, BI Cho, K Engelhorn, H-K Chung, CRD Brown, T Burian, J Chalupský, RW Falcone, C Graves, V Hájková, A Higginbotham, L Juha, J Krzywinski, HJ Lee, M Messerschmidt, C Murphy, Y Ping, A Scherz, W Schlotter, S Toleikis, JJ Turner, L Vysin, T Wang, B Wu, U Zastrau, D Zhu, B Nagler, RW Lee, PA Heimann, JS Wark

Combined Hydrodynamic and Diffraction Simulations of Femtosecond X-ray Scattering from Laser-Shocked Crystals

Journal of Physics Conference Series IOP Publishing 500:15 (2014) 152016

Authors:

Justin S Wark, Andrew Higginbotham, Despina Milathianaki, Arianna Gleason

Investigations into rapid uniaxial compression of polycrystalline targets using femtosecond X-ray diffraction

Journal of Physics Conference Series IOP Publishing 500:11 (2014) 112063

Authors:

David McGonegle, Andrew Higginbotham, Eric Galtier, Emma E McBride, Malcolm I McMahon, Despina Milathianaki, Hae Ja Lee, Bob Nagler, Sam M Vinko, Justin S Wark

Shock waves in polycrystalline iron: Plasticity and phase transitions

Physical Review B American Physical Society (APS) 89:14 (2014) 140102

Authors:

Nina Gunkelmann, Eduardo M Bringa, Diego R Tramontina, Carlos J Ruestes, Matthew J Suggit, Andrew Higginbotham, Justin S Wark, Herbert M Urbassek

Density functional theory calculations of continuum lowering in strongly coupled plasmas.

Nature communications 5 (2014) 3533-3533

Authors:

SM Vinko, O Ciricosta, JS Wark

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.