Advanced search

Filter By:

Journal Check one or more journals to show results from those journals only.

Choose more journals

Article type Check one or more article types to show results from those article types only.
Subject Check one or more subjects to show results from those subjects only.
Date Choose a date option to show results from those dates only.

Custom date range

Clear all filters
Sort by:
Showing 1–9 of 9 results
Advanced filters: Author: Justin S. Wark Clear advanced filters

  • There has long been a desire for ultrashort X-ray diffraction to study structures that change in real time. Large synchotron sources can generate X-ray pulses lasting less than a picosecond. Now, advances in high-power lasers have brought sub-picosecond X-ray diffraction to the laboratory bench — to probe the physics of ultrasonic waves in a semiconductor crystal.

    • Justin Wark
    News & Views
    Nature
    Volume: 398, P: 284-285

  • Intense lasers enable scientists to study the behaviour of matter under extreme pressures, but obtaining information about its atomic structure is challenging. In this work, Suggit et al. demonstrate the use of white-light X-ray diffraction to probe the structure of laser-shocked copper on nanosecond timescales.

    • Matthew J. Suggit
    • Andrew Higginbotham
    • Justin S. Wark
    Research
    Nature Communications
    Volume: 3, P: 1-6

  • The first experimental demonstration of saturable absorption in core-electron transitions in aluminium paves the way for investigating warm dense matter, which potentially has an important role in planetary science and the realization of inertial confinement fusion.

    • Bob Nagler
    • Ulf Zastrau
    • Justin S. Wark
    Research
    Nature Physics
    Volume: 5, P: 693-696

  • The world's first kiloelectronvolt X-ray laser produces such a high flux of photons that atoms can be 'cored'. In other words, the light source can knock out both the electrons of an atom's innermost shell.

    • Justin Wark
    News & Views
    Nature
    Volume: 466, P: 35-36

  • The authors combine differentiable physics modelling and neural networks to extract high-resolution electronic density of states of warm dense materials from resonant inelastic x-ray scattering spectra. With this approach, they identify distinctive features in the valence structures of warm dense Fe and Fe2O3, also estimating their temperature and M-shell binding energies.

    • Alessandro Forte
    • Thomas Gawne
    • Sam M. Vinko
    ResearchOpen Access
    Communications Physics
    Volume: 7, P: 1-9

  • X-ray free-electron lasers enable a range of new experimental investigations into the properties of matter driven to extreme conditions via intense x-ray-matter interaction. The proposed numerical method enables a quantitative investigation of transient high-energy-density plasmas driven by XFELs in femtosecond timescales even when both electrons and ions are far from local thermodynamic equilibrium.

    • Shenyuan Ren
    • Yuanfeng Shi
    • Sam M. Vinko
    ResearchOpen Access
    Communications Physics
    Volume: 6, P: 1-10