Laboratory astroparticle physics

Thomson scattering measurements in atmospheric plasma jets

Physical Review E - Statistical Physics, Plasmas, Fluids, and Related Interdisciplinary Topics 59:2 (1999) 2286-2291

Authors:

G Gregori, J Schein, P Schwendinger, U Kortshagen, J Heberlein, E Pfender

Abstract:

Electron temperature and electron density in a dc plasma jet at atmospheric pressure have been obtained using Thomson laser scattering. Measurements performed at various scattering angles have revealed effects that are not accounted for by the standard scattering theory. Differences between the predicted and experimental results suggest that higher order corrections to the theory may be required, and that corrections to the form of the spectral density function may play an important role. © 1999 The American Physical Society.

A study of picosecond laser–solid interactions up to 1019 W cm−2

Physics of Plasmas AIP Publishing 4:2 (1997) 447-457

Authors:

FN Beg, AR Bell, AE Dangor, CN Danson, AP Fews, ME Glinsky, BA Hammel, P Lee, PA Norreys, M Tatarakis

A proposal to use accelerated electrons to probe the axion-electron coupling

Physical Review Letters American Physical Society

Authors:

Georgios Vacalis, Atsushi Higuchi, Robert Bingham, Gianluca Gregori

Abstract:

The axion is a hypothetical particle associated with a possible solution to the strong CP problem and is a leading candidate for dark matter. In this paper we investigate the emission of axions by accelerated electrons. We find the emission probability and energy within the WKB approximation for an electron accelerated by an electromagnetic field. As an application, we estimate the number of axions produced by electrons accelerated using two counter-propagating high-intensity lasers and discuss how they would be converted to photons to be detected. We find that, under realistic experimental conditions, competitive model-independent bounds on the coupling between the axion and the electron could be achieved in such an experiment.

Fast Non-Adiabatic Dynamics of Many-Body Quantum Systems

Science Advances Springer Verlag

Authors:

Brett Larder, Dirk Gericke, Scott Richardson, Paul Mabey, Thomas White, Gianluca Gregori

Abstract:

Modeling many-body quantum systems with strong interactions is one of the core challenges of modern physics. A range of methods has been developed to approach this task, each with its own idiosyncrasies, approximations, and realm of applicability. Perhaps the most successful and ubiquitous of these approaches is density functional theory (DFT). Its Kohn-Sham formulation has been the basis for many fundamental physical insights, and it has been successfully applied to fields as diverse as quantum chemistry, condensed matter and dense plasmas. Despite the progress made by DFT and related schemes, however, there remain many problems that are intractable for existing methods. In particular, many approaches face a huge computational barrier when modeling large numbers of coupled electrons and ions at finite temperature. Here, we address this shortfall with a new approach to modeling many-body quantum systems. Based on the Bohmian trajectories formalism, our new method treats the full particle dynamics with a considerable increase in computational speed. As a result, we are able to perform large-scale simulations of coupled electron-ion systems without employing the adiabatic Born-Oppenheimer approximation.

Inverse Problem Instabilities in Large-Scale Plasma Modelling

Authors:

MF Kasim, TP Galligan, J Topp-Mugglestone, G Gregori, SAM Vinko

Abstract:

Our understanding of physical systems generally depends on our ability to match complex computational modelling with measured experimental outcomes. However, simulations with large parameter spaces suffer from inverse problem instabilities, where similar simulated outputs can map back to very different sets of input parameters. While of fundamental importance, such instabilities are seldom resolved due to the intractably large number of simulations required to comprehensively explore parameter space. Here we show how Bayesian machine learning can be used to address inverse problem instabilities, and apply it to two popular experimental diagnostics in plasma physics. We find that the extraction of information from measurements simply on the basis of agreement with simulations is unreliable, and leads to a significant underestimation of uncertainties. We describe how to statistically quantify the effect of unstable inverse models, and describe an approach to experimental design that mitigates its impact.