Oxford Centre for High Energy Density Science (OxCHEDS)

Experimental observation of open structures in elemental magnesium at terapascal pressures

Nature Physics Springer Nature 18:11 (2022) 1307-1311

Authors:

MG Gorman, S Elatresh, A Lazicki, MME Cormier, S Bonev, D McGonegle, R Briggs, AL Coleman, SD Rothman, L Peacock, J Bernier, F Coppari, DG Braun, JR Rygg, DE Fratanduono, R Hoffmann, GW Collins, Justin Wark, RF Smith, JH Eggert, MI McMahon

Abstract:

Investigating how solid matter behaves at enormous pressures, such as those found in the deep interiors of giant planets, is a great experimental challenge. Over the past decade, computational predictions have revealed that compression to terapascal pressures may bring about counter-intuitive changes in the structure and bonding of solids as quantum mechanical forces grow in influence1,2,3,4,5,6. Although this behaviour has been observed at modest pressures in the highly compressible light alkali metals7,8, it has not been established whether it is commonplace among high-pressure solids more broadly. We used shaped laser pulses at the National Ignition Facility to compress elemental Mg up to 1.3 TPa, which is approximately four times the pressure at the Earth’s core. By directly probing the crystal structure using nanosecond-duration X-ray diffraction, we found that Mg changes its crystal structure several times with non-close-packed phases emerging at the highest pressures. Our results demonstrate that phase transformations of extremely condensed matter, previously only accessible through theoretical calculations, can now be experimentally explored.

Experimental observation of open structures in elemental magnesium at terapascal pressures

Nature Physics Springer Nature 18:11 (2022) 1307-1311

Authors:

Mg Gorman, S Elatresh, A Lazicki, Mme Cormier, Sa Bonev, D McGonegle, R Briggs, Al Coleman, Sd Rothman, L Peacock, Jv Bernier, F Coppari, Dg Braun, Jr Rygg, De Fratanduono, R Hoffmann, Gw Collins, Js Wark, Rf Smith, Jh Eggert, Mi McMahon

Abstract:

Investigating how solid matter behaves at enormous pressures, such as those found in the deep interiors of giant planets, is a great experimental challenge. Over the past decade, computational predictions have revealed that compression to terapascal pressures may bring about counter-intuitive changes in the structure and bonding of solids as quantum mechanical forces grow in influence^1,2,3,4,5,6. Although this behaviour has been observed at modest pressures in the highly compressible light alkali metals^7,8, it has not been established whether it is commonplace among high-pressure solids more broadly. We used shaped laser pulses at the National Ignition Facility to compress elemental Mg up to 1.3 TPa, which is approximately four times the pressure at the Earth’s core. By directly probing the crystal structure using nanosecond-duration X-ray diffraction, we found that Mg changes its crystal structure several times with non-close-packed phases emerging at the highest pressures. Our results demonstrate that phase transformations of extremely condensed matter, previously only accessible through theoretical calculations, can now be experimentally explored.

Stabilized radiation pressure acceleration and neutron generation in ultrathin deuterated foils

Physical Review Letters American Physical Society 129:11 (2022) 114801

Authors:

A Alejo, H Ahmed, Ag Krygier, R Clarke, Rr Freeman, J Fuchs, A Green, Js Green, D Jung, A Kleinschmidt, Jt Morrison, Z Najmudin, H Nakamura, P Norreys, M Notley, M Oliver, M Roth, L Vassura, M Zepf, M Borghesi, S Kar

Abstract:

Premature relativistic transparency of ultrathin, laser-irradiated targets is recognized as an obstacle to achieving a stable radiation pressure acceleration in the "light sail" (LS) mode. Experimental data, corroborated by 2D PIC simulations, show that a few-nm thick overcoat surface layer of high Z material significantly improves ion bunching at high energies during the acceleration. This is diagnosed by simultaneous ion and neutron spectroscopy following irradiation of deuterated plastic targets. In particular, copious and directional neutron production (significantly larger than for other in-target schemes) arises, under optimal parameters, as a signature of plasma layer integrity during the acceleration.

Optimising point source irradiation of a capsule for maximum uniformity

High Energy Density Physics Elsevier 45 (2022) 101007

Authors:

Oliver Breach, Peter Hatfield, Steven Rose

Abstract:

Inertial Confinement Fusion involves the implosion of a spherical capsule containing thermonuclear fuel. The implosion is driven by irradiating the outside of the capsule by X-rays or by optical laser irradiation, where in each case the highest uniformity of irradiation is sought. In this paper we consider the theoretical problem of irradiation of a capsule by point sources of X-rays, and configurations which maximize uniformity are sought. By studying the root-mean-square deviation in terms of different order harmonic modes, we rationalise the dependence of uniformity on distance d of the point sources from the centre of a capsule. After investigating simple configurations based on the Platonic solids, we use a global optimisation algorithm (basin-hopping) to seek better arrangements. The optimum configurations are found to depend strongly on d; at certain values which minimise nonuniformity, these involve grouping of sources on the vertices of octahedra or icosahedra, which we explain using a modal decomposition. The effect of uncertainties in both position and intensity is studied, and lastly we investigate the illumination of a capsule whose radius is changing with time.

Femtosecond diffraction and dynamic high pressure science

Journal of Applied Physics AIP Publishing 132 (2022) 080902

Authors:

Justin Wark, Malcolm I McMahon, Jon H Eggert

Abstract:

Solid-state material at high pressure is prevalent throughout the Universe, and an understanding of the structure of matter under such extreme conditions, gleaned from x-ray diffraction, has been pursued for the best part of a century. The highest pressures that can be reached to date (2 TPa) in combination with x-ray diffraction diagnosis have been achieved by dynamic compression via laser ablation [A. Lazicki et al., Nature 589, 532–535 (2021)]. The past decade has witnessed remarkable advances in x-ray technologies, with novel x-ray Free-Electron-Lasers (FELs) affording the capacity to produce high quality single-shot diffraction data on timescales below 100 fs. We provide a brief history of the field of dynamic compression, spanning from when the x-ray sources were almost always laser-plasma based, to the current state-of-the art diffraction capabilities provided by FELs. We give an overview of the physics of dynamic compression, diagnostic techniques, and the importance of understanding how the rate of compression influences the final temperatures reached. We provide illustrative examples of experiments performed on FEL facilities that are starting to give insight into how materials deform at ultrahigh strain rates, their phase diagrams, and the types of states that can be reached. We emphasize that there often appear to be differences in the crystalline phases observed between the use of static and dynamic compression techniques. We give our perspective on both the current state of this rapidly evolving field and some glimpses of how we see it developing in the near-to-medium term.