Dr Ramy Aboushelbaya

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.

Pathways towards break even for low convergence ratio direct-drive inertial confinement fusion

Journal of Plasma Physics Cambridge University Press 88:3 (2022) 905880314

Authors:

Rw Paddock, H Martin, Rt Ruskov, Rhh Scott, W Garbett, Bm Haines, Ab Zylstra, Em Campbell, Tjb Collins, Rs Craxton, Ca Thomas, Vn Goncharov, R Aboushelbaya, Qs Feng, Mw von der Leyen, I Ouatu, Bt Spiers, R Timmis, Rhw Wang, Pa Norreys

Abstract:

Following indirect-drive experiments which demonstrated promising performance for low convergence ratios (below 17), previous direct-drive simulations identified a fusion-relevant regime which is expected to be robust to hydrodynamic instability growth. This paper expands these results with simulated implosions at lower energies of 100 and 270 kJ, and ‘hydrodynamic equivalent’ capsules which demonstrate comparable convergence ratio, implosion velocity and in-flight aspect ratio without the need for cryogenic cooling, which would allow the assumptions of one-dimensional-like performance to be tested on current facilities. A range of techniques to improve performance within this regime are then investigated, including the use of two-colour and deep ultraviolet laser pulses. Finally, further simulations demonstrate that the deposition of electron energy into the hotspot of a low convergence ratio implosion through auxiliary heating also leads to significant increases in yield. Results include break even for 1.1 MJ of total energy input (including an estimated 370 kJ of short-pulse laser energy to produce electron beams for the auxiliary heating), but are found to be highly dependent upon the efficiency with which electron beams can be created and transported to the hotspot to drive the heating mechanism.

One-dimensional hydrodynamic simulations of low convergence ratio direct-drive inertial confinement fusion implosions

Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences The Royal Society 379:2189 (2020) 20200224

Authors:

Robert Paddock, Heath Martin, Rusko Ruskov, Robbie Scott, Warren Garbett, Brian Haines, Alex Zylstra, Ramy Aboushelbaya, Marko Mayr, Benjamin Spiers, Robin Wang, Peter Norreys

Abstract:

Indirect drive inertial confinement fusion experiments with convergence ratios below 17 have been previously shown to be less susceptible to Rayleigh-Taylor hydrodynamic instabilities, making this regime highly interesting for fusion science. Additional limitations imposed on the implosion velocity, in-flight aspect ratio and applied laser power aim to further reduce instability growth, resulting in a new regime where performance can be well represented by one-dimensional (1D) hydrodynamic simulations. A simulation campaign was performed using the 1D radiation-hydrodynamics code HYADES to investigate the performance that could be achieved using direct drive implosions of liquid layer capsules, over a range of relevant energies. Results include potential gains of 0.19 on LMJ-scale systems and 0.75 on NIF-scale systems, and a reactor-level gain of 54 for an 8.5 MJ implosion. While the use of 1D simulations limits the accuracy of these results, they indicate a sufficiently high level of performance to warrant further investigations and verification of this new low-instability regime. This potentially suggests an attractive new approach to fusion energy.

Preparations for a European R&D roadmap for an inertial fusion demo reactor

Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences The Royal Society 379 (2020) 20200005

Authors:

Peter Norreys, Luke Ceurvorst, James Sadler, Benjamin Spiers, Ramy Aboushelbaya, Marko Mayr, Robert Paddock, Naren Ratan, Alexander Savin, Kevin Glize, Raoul Trines, Bob Bingham, Matthew Hill, Nathan Sircombe, Peter Allan, Laura Hobbs, Steve James, James Skidmore, J Fyrth, J Luis, Emma Floyd, Colin Brown, Brian Haines, Re Olson, Sa Yi, Ab Zylstra, K Flippo, Pa Bradley, Rr Peterson, Jl Kline, Rj Leeper

Abstract:

A European consortium of 15 laboratories across nine nations have worked together under the EUROFusion Enabling Research grants for the past decade with three principle objectives. These are: (a) investigating obstacles to ignition on megaJoule-class laser facilities; (b) investigating novel alternative approaches to ignition, including basic studies for fast ignition (both electron and ion-driven), auxiliary heating, shock ignition, etc.; and (c) developing technologies that will be required in the future for a fusion reactor. A brief overview of these activities, presented here, along with new calculations relates the concept of auxiliary heating of inertial fusion targets, and provides possible future directions of research and development for the updated European Roadmap that is due at the end of 2020.

Whole-beam self-focusing in fusion-relevant plasma

Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences Royal Society 379:2189 (2020) 20200159

Authors:

Benjamin Spiers, Matthew Hill, Colin Brown, Luke Ceurvorst, Naren Ratan, Alexander Savin, P Allan, Emma Floyd, J Fyrth, L Hobbs, S James, J Luis, M Ramsay, Nathan Sircombe, J Skidmore, Ramy Aboushelbaya, Marko Mayr, Robert Paddock, Rhw Wang, Peter Norreys

Abstract:

Fast ignition inertial confinement fusion requires the production of a low-density channel in plasma with density scale-lengths of several hundred microns. The channel assists in the propagation of an ultra-intense laser pulse used to generate fast electrons which form a hot spot on the side of pre-compressed fusion fuel. We present a systematic characterisation of an expanding laser-produced plasma using optical interferometry, benchmarked against three-dimensional hydrodynamic simulations. Magnetic fields associated with channel formation are probed using proton radiography, and compared to magnetic field structures generated in fullscale particle-in-cell simulations. We present observations of long lived, straight channels produced by the Habara-Kodama-Tanaka (HKT) wholebeam self-focusing mechanism, overcoming a critical barrier on the path to realising fast ignition.