Litcius/Paper detail

Controlling morphology and improving reproducibility of magnetized liner inertial fusion experiments

D. J. Ampleford, David Yager-Elorriaga, C. A. Jennings, Eric Harding, M. R. Gómez, A. J. Harvey-Thompson, T. J. Awe, G. A. Chandler, G. S. Dunham, Matthias Geißel, Kelly Hahn, Stephanie B. Hansen, Patrick Knapp, Derek C. Lamppa, William Lewis, Larry Lucero, Michael Mangan, R. R. Paguio, L. Perea, G. A. Robertson, C. L. Ruiz, D. E. Ruiz, Paul Schmit, S. A. Slutz, G. E. Smith, I. C. Smith, Christopher Speas, Timothy Webb, Matthew Weis, K. Whittemore, Edmund Yu, R. D. McBride, Kyle Peterson, B. M. Jones, G. A. Rochau, D. B. Sinars

2024Physics of Plasmas16 citationsDOIOpen Access PDF

Abstract

X-ray imaging indicates magnetized liner inertial fusion (MagLIF) stagnation columns have a complicated quasi-helical structure with significant variations in x-ray brightness along the column. In this work, we describe MagLIF experiments aimed at controlling these stagnation structures by varying the initial liner geometry and composition. First, by varying the initial aspect ratio of the liner, we demonstrate a change in the stagnation structures that is consistent with helical magneto Rayleigh–Taylor (MRT) instabilities feedthrough from the outer-to-inner surfaces of the liner. Second, to minimize the seed for such instabilities, we incorporate a dielectric coating on the outer surface of the beryllium liner, which has previously been shown to reduce the growth of the electrothermal instability, a likely seed for MRT growth. Using this coating, we achieve a stagnation column with significantly reduced helical structure and axial variation in x-ray brightness. We discuss how this coating changes the evolution of structures through stagnation along with the spatial uniformity of neutron production. Finally, we show that these more uniform stagnations also result in improved reproducibility in stagnation temperatures and primary DD neutron yield.

Topics & Concepts

PhysicsFeedthroughRayleigh–Taylor instabilityInertial confinement fusionStagnation pressureMechanicsCoatingInstabilityBerylliumPlasmaOpticsComposite materialMaterials scienceNuclear physicsOptoelectronicsMach numberLaser-Plasma Interactions and DiagnosticsMagnetic confinement fusion researchHigh-pressure geophysics and materials
Controlling morphology and improving reproducibility of magnetized liner inertial fusion experiments | Litcius