Oxford Centre for High Energy Density Science (OxCHEDS)

Parametric co-linear axion photon instability

Physics Letters B Elsevier 839 (2023) 137759

Authors:

Ka Beyer, G Marocco, C Danson, R Bingham, G Gregori

Abstract:

Axions and axion-like particles generically couple to QED via the axion-photon-photon interaction. This leads to a modification of Maxwell's equations known in the literature as axion-electrodynamics. The new form of Maxwell's equations gives rise to a new parametric instability in which a strong pump decays into a scattered light wave and an axion. This axion mode grows exponentially in time and leads to a change in the polarisation of the initial laser beam, therefore providing a signal for detection. Currently operating laser systems can put bounds on the axion parameter space, however longer pulselengths are necessary to reach the current best laboratory bounds of light-shining through wall experiments.

Investigating Mechanisms of State Localization in Highly-Ionized Dense Plasmas

(2023)

Authors:

Thomas Gawne, Thomas Campbell, Alessandro Forte, Patrick Hollebon, Gabriel Perez-Callejo, Oliver Humphries, Oliver Karnbach, Muhammad F Kasim, Thomas R Preston, Hae Ja Lee, Alan Miscampbell, Quincy Y van den Berg, Bob Nagler, Shenyuan Ren, Ryan B Royle, Justin S Wark, Sam M Vinko

Towards more robust ignition of inertial fusion targets

Physics of Plasmas AIP Publishing 30 (2023) 022702

Authors:

Jordan Lee, Rusko T Ruskov, Heath S Martin, Stephen Hughes, Marko W von der Leyen, Robert W Paddock, Robin Timmis, Iustin Ouatu, Qingsong S Feng, Sunny Howard, Eduard Atonga, Ramy Aboushelbaya, TD Arber, R Bingham, Peter Norreys

Abstract:

Following the 1.3 MJ fusion milestone at the National Ignition Facility, the further development of inertial confinement fusion, both as a source for future electricity generation and for high energy density physics applications, requires the development of more robust ignition concepts at current laser facility energy scales. This can potentially be achieved by auxiliary heating the hotspot of low convergence wetted foam implosions where hydrodynamic and parametric instabilities are minimised. This paper presents the first multi-dimensional Vlasov-Maxwell and particle-in-cell simulations to model this collisionless interaction, only recently made possible by access to the largest modern supercomputers. The key parameter of interest is the maximum fraction of energy that can be extracted from the electron beams into the hotspot plasma. The simulations indicate that significant coupling efficiencies are achieved over a wide range of beam parameters and spatial configurations. The implications for experimental tests on the National Ignition Facility are discussed.

Detection of high-frequency gravitational waves using high-energy pulsed lasers

(2023)

Authors:

Georgios Vacalis, Giacomo Marocco, James Bamber, Robert Bingham, Gianluca Gregori

Measuring Unruh radiation from accelerated electrons

(2023)

Authors:

Gianluca Gregori, Giacomo Marocco, Subir Sarkar, Robert Bingham, Charles Wang