Professor Justin Wark

Single photon energy dispersive x-ray diffraction.

The Review of scientific instruments 85:3 (2014) 033906

Authors:

Andrew Higginbotham, Shamim Patel, James A Hawreliak, Orlando Ciricosta, Gilbert W Collins, Federica Coppari, Jon H Eggert, Matthew J Suggit, Henry Tang, Justin S Wark

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

Authors:

Gabriele Mogni, Andrew Higginbotham, Katalin Gaál-Nagy, Nigel Park, Justin S Wark

Imaging Lattice dynamics in individual nanocrystals

Optics InfoBase Conference Papers (2014)

Authors:

JN Clark, L Beitra, G Xiong, A Higginbotham, DM Fritz, HT Lemke, D Zhu, M Chollet, GJ Williams, M Messerschmidt, B Abbey, RJ Harder, AM Korsunsky, JS Wark, IK Robinson

Abstract:

We report imaging of coherent acoustic phonons on the picosecond time scale within a single nanocrystal using an X-ray free-electron laser. Our results allow unprecedented comparison with predictive models and observation of the vibrational modes. © 2014 OSA.

Imaging Lattice dynamics in individual nanocrystals

Optica Publishing Group (2014) 09.wed.e.1

Authors:

JN Clark, L Beitra, G Xiong, A Higginbotham, DM Fritz, HT Lemke, D Zhu, M Chollet, GJ Williams, M Messerschmidt, B Abbey, RJ Harder, AM Korsunsky, JS Wark, IK Robinson

Fourier-transform inelastic X-ray scattering from time- and momentum-dependent phonon-phonon correlations

Nature Physics (2013)

Authors:

M Trigo, M Fuchs, J Chen, MP Jiang, AM Lindenberg, DA Reis, K Gaffney, S Ghimire, ME Kozina, G Ndabashimiye, M Cammarata, DM Fritz, H Lemke, D Zhu, S Fahy, A Higginbotham, JS Wark, SL Johnson, J Larsson, F Quirin, K Sokolowski-Tinten, C Uher, G Wang

Abstract:

The macroscopic characteristics of a material are determined by its elementary excitations, which dictate the response of the system to external stimuli. The spectrum of excitations is related to fluctuations in the density-density correlations and is typically measured through frequency-domain neutron or X-ray scattering. Time-domain measurements of these correlations could yield a more direct way to investigate the excitations of solids and their couplings both near to and far from equilibrium. Here we show that we can access large portions of the phonon dispersion of germanium by measuring the diffuse scattering from femtosecond X-ray free-electron laser pulses. A femtosecond optical laser pulse slightly quenches the vibrational frequencies, producing pairs of high-wavevector phonons with opposite momenta. These phonons manifest themselves as time-dependent coherences in the displacement correlations probed by the X-ray scattering. As the coherences are preferentially created in regions of strong electron-phonon coupling, the time-resolved approach is a natural spectroscopic tool for probing low-energy collective excitations in solids, and their microscopic interactions.