Oxford Centre for High Energy Density Science (OxCHEDS)

Relativistic harmonics in the efficiency limit

Nature Nature Research (2025)

Authors:

robin Timmis, Colm Fitzpatrick, Jonathan Kennedy, Holly Huddleston, Elliott Denis, Abigail James, Chris Baird, Dan Symes, David McGonegle, Eduard Atonga, Heath Martin, Jeremy Rebenstock, John Neely, Jordan Lee, Nicolas Bourgeois, Oliver Finlay, Rusko Ruskov, Sam Astbury, Steve Hawkes, Matt Zepf, Karl Krushelnick, Edward Gumbrell, Rajeev Pattathil, Mark Yeung, Brendan Dromey, Peter Norreys

Testing strong-field QED with the avalanche precursor

Physics of Plasmas American Institute of Physics 32:9 (2025) 093302

Abstract:

A two-beam high-power laser facility is essential for the study of one of the most captivating phenomena predicted by strong-field quantum electrodynamics (QED) and yet unobserved experimentally: the avalanchetype cascade. In such a cascade, the energy of intense laser light can be efficiently transformed into high-energy radiation and electron-positron pairs. The future 50-petawatt-scale laser facility NSF OPAL will provide unique opportunities for studying such strong-field QED effects, as it is designed to deliver two ultra-intense, tightly focused laser pulses onto the interaction point. In this work, we investigate the potential of such a facility for studying elementary particle and plasma dynamics deeply in the quantum radiation-dominated regime, and the generation of QED avalanches. With 3D particle-in-cell simulations, we demonstrate that QED avalanche precursors can be reliably triggered under realistic laser parameters and layout (namely, focusing f /2, tilted optical axes, and non-ideal co-pointing) with the anticipated capabilities of NSF OPAL. We demonstrate that seed electrons can be efficiently injected into the laser focus by using targets of three types: a gas of heavy atoms, an overcritical plasma, and a thin foil. A strong positron and high-energy photon signal is generated in all cases. The cascade properties can be identified from the final particle distributions, which have a clear directional pattern. At increasing laser field intensity, such distributions provide signatures of the transition, first, to the radiation-dominated interaction regime, and then to a QED avalanche. Our findings can also be used for designing related future experiments.

Larmor radiation as a witness to the Unruh effect

Physical Review D American Physical Society (APS) 112:6 (2025) 65009

Authors:

Atsushi Higuchi, George EA Matsas, Daniel AT Vanzella, Robert Bingham, João PB Brito, Luís CB Crispino, Gianluca Gregori, Georgios Vacalis

Abstract:

<jats:p>We discuss the emission of radiation from general sources in quantum scalar, electromagnetic, and gravitational fields using the Rindler coordinate frame, which is suitable for uniformly accelerated observers, in the Minkowski vacuum. In particular, we point out that to recover, from the point of view of uniformly accelerated observers in the interaction picture, the usual Larmor radiation, which is independent of the choice of the vacuum state, it is necessary to incorporate the Unruh effect assuming the Minkowski vacuum. Thus, the observation of classical Larmor radiation in the Minkowski vacuum could be seen as vindicating the Unruh effect in the sense that it is not correctly recovered in the uniformly accelerated frame unless the Unruh effect is taken into account.</jats:p>

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

(2025)

Authors:

Charles D Arrowsmith, Francesco Miniati, Pablo J Bilbao, Pascal Simon, Archie FA 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, Tom Hodge, Brian T Huffman, Sam Iaquinta, G Marshall, Brian Reville, Subir Sarkar, Alexander A Schekochihin, Luis O Silva, Raspberry Simpson, Vasiliki Stergiou, Raoul MGM Trines, Thibault Vieu, Nikolaos Charitonidis, Robert Bingham, Gianluca Gregori

High-quality ultra-fast total scattering and pair distribution function data using an X-ray free-electron laser.

IUCrJ International Union of Crystallography (IUCr) 12:5 (2025)

Authors:

Adam F Sapnik, Philip A Chater, Dean S Keeble, John SO Evans, Federica Bertolotti, Antonietta Guagliardi, Lise J Støckler, Elodie A Harbourne, Anders B Borup, Rebecca S Silberg, Adrien Descamps, Clemens Prescher, Benjamin D Klee, Axel Phelipeau, Imran Ullah, Kárel G Medina, Tobias A Bird, Viktoria Kaznelson, William Lynn, Andrew L Goodwin, Bo B Iversen, Celine Crepisson, Emil S Bozin, Kirsten MØ Jensen, Emma E McBride, Reinhard B Neder, Ian Robinson, Justin S Wark, Michał Andrzejewski, Ulrike Boesenberg, Erik Brambrink, Carolina Camarda, Valerio Cerantola, Sebastian Goede, Hauke Höppner, Oliver S Humphries, Zuzana Konopkova, Naresh Kujala, Thomas Michelat, Motoaki Nakatsutsumi, Alexander Pelka, Thomas R Preston, Lisa Randolph, Michael Roeper, Andreas Schmidt, Cornelius Strohm, Minxue Tang, Peter Talkovski, Ulf Zastrau, Karen Appel, David A Keen

Abstract:

High-quality total scattering data, a key tool for understanding atomic-scale structure in disordered materials, require stable instrumentation and access to high momentum transfers. This is now routine at dedicated synchrotron instrumentation using high-energy X-ray beams, but it is very challenging to measure a total scattering dataset in less than a few microseconds. This limits their effectiveness for capturing structural changes that occur at the much faster timescales of atomic motion. Current X-ray free-electron lasers (XFELs) provide femtosecond-pulsed X-ray beams with maximum energies of ∼24 keV, giving the potential to measure total scattering and the attendant pair distribution functions (PDFs) on femtosecond timescales. We demonstrate that this potential has been realized using the HED scientific instrument at the European XFEL and present normalized total scattering data for 0.35 Å^-1 < Q < 16.6 Å^-1 and their PDFs from a broad spectrum of materials, including crystalline, nanocrystalline and amorphous solids, liquids and clusters in solution. We analyzed the data using a variety of methods, including Rietveld refinement, small-box PDF refinement, joint reciprocal-real-space refinement, cluster refinement and Debye scattering analysis. The resolution function of the setup is also characterized. We conclusively show that high-quality data can be obtained from a single ∼30 fs XFEL pulse for multiple different sample types. Our efforts not only significantly increase the existing maximum reported Q range for an S(Q) measured at an XFEL but also mean that XFELs are now a viable X-ray source for the broad community of people using reciprocal-space total scattering and PDF methods in their research.