Oxford Centre for High Energy Density Science (OxCHEDS)

A comparison of time-dependent Cloudy astrophysical code simulations with experimental X-ray spectra from keV laser-generated argon plasmas

Journal of Quantitative Spectroscopy and Radiative Transfer Elsevier BV 348 (2026) 109720

Authors:

N Rathee, Fp Keenan, Rjr Williams, Gj Ferland, Sj Rose, S White, D Riley

Erratum: “X-ray diffraction at the National Ignition Facility” [Rev. Sci. Instrum. 91, 043902 (2020)]

Review of Scientific Instruments AIP Publishing 97:1 (2026) 019901

Authors:

JR Rygg, RF Smith, AE Lazicki, DG Braun, DE Fratanduono, RG Kraus, JM McNaney, DC Swift, CE Wehrenberg, F Coppari, MF Ahmed, MA Barrios, KJM Blobaum, GW Collins, AL Cook, P Di Nicola, EG Dzenitis, S Gonzales, BF Heidl, M Hohenberger, A House, N Izumi, DH Kalantar, SF Khan, TR Kohut, C Kumar, ND Masters, DN Polsin, SP Regan, CA Smith, RM Vignes, MA Wall, J Ward, JS Wark, TL Zobrist, A Arsenlis, JH Eggert

Emission of pairs of Minkowski photons through the lens of the Unruh effect

Physical Review D American Physical Society (APS) (2025)

Cosmic-ray transport in inhomogeneous media

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 545:2 (2025) staf2108

Authors:

Robert J Ewart, Patrick Reichherzer, Shuzhe Ren, Stephen Majeski, Francesco Mori, Michael L Nastac, Archie FA Bott, Matthew W Kunz, Alexander A Schekochihin

Abstract:

ABSTRACT A theory of cosmic-ray transport in multiphase diffusive media is developed, with the specific application to cases in which the cosmic-ray diffusion coefficient has large spatial fluctuations that may be inherently multiscale. We demonstrate that the resulting transport of cosmic rays is diffusive in the long-time limit, with an average diffusion coefficient equal to the harmonic mean of the spatially varying diffusion coefficient. Thus, cosmic-ray transport is dominated by areas of low diffusion even if these areas occupy a relatively small, but not infinitesimal, fraction of the volume. On intermediate time-scales, the cosmic rays experience transient effective subdiffusion, as a result of low-diffusion regions interrupting long flights through high-diffusion regions. In the simplified case of a two-phase medium, we show that the extent and extremity of the subdiffusivity of cosmic-ray transport is controlled by the spectral exponent of the distribution of patch sizes of each of the phases. We finally show that, despite strongly influencing the confinement times, the multiphase medium is only capable of altering the energy dependence of cosmic-ray transport when there is a moderate (but not excessive) level of perpendicular diffusion across magnetic-field lines.

Suppression of pair beam instabilities in a laboratory analogue of blazar pair cascades

Proceedings of the National Academy of Sciences National Academy of Sciences 122:45 (2025) e2513365122

Authors:

Charles Arrowsmith, Francesco Miniati, Pablo J Bilbao, Pascal Simon, Archie Bott, Stephane Burger, Hui Chen, Filipe D Cruz, Tristan Davenne, Anthony Dyson, Ilias Efthymiopoulos, Dustin H Froula, Alice Goillot, Jon T Gudmundsson, Dan Haberberger, Jack WD Halliday, Thomas Hodge, Brian T Huffman, Sam Iaquinta, G Marshall, Brian Reville, Subir Sarkar, Alexander Schekochihin, Luis O Silva, Raspberry Simpson, Vasiliki Stergiou, Raoul MGM Trines, Thibault Vieu, Nikolaos Charitonidis, Robert Bingham, Gianluca Gregori

Abstract:

The generation of dense electron-positron pair beams in the laboratory can enable direct tests of theoretical models of γ-ray bursts and active galactic nuclei. We have successfully achieved this using ultrarelativistic protons accelerated by the Super Proton Synchrotron at (CERN). In the first application of this experimental platform, the stability of the pair beam is studied as it propagates through a meter-length plasma, analogous to TeV γ-ray-induced pair cascades in the intergalactic medium. It has been argued that pair beam instabilities disrupt the cascade, thus accounting for the observed lack of reprocessed GeV emission from TeV blazars. If true, this would remove the need for a moderate strength intergalactic magnetic field to explain the observations. We find that the pair beam instability is suppressed if the beam is not perfectly collimated or monochromatic, hence the lower limit to the intergalactic magnetic field inferred from γ-ray observations of blazars is robust.