Performance Scaling in Magnetized Liner Inertial Fusion Experiments

Gómez, M. R.; Slutz, Stephen A.; Jennings, Christopher; Ampleford, D. J.; Weis, Matthew; Myers, C. E.; Yager-Elorriaga, D. A.; Hahn, Kelly; Hansen, Stephanie B.; Harding, Eric; Harvey‐Thompson, A. J.; Lamppa, Derek C.; Mangan, M. A.; Knapp, Patrick; Awe, T. J.; Chandler, G. A.; Cooper, G. W.; Fein, Jeffrey; Geißel, Matthias; Glinsky, Michael E.; Lewis, William E.; Ruiz, C. L.; Ruiz, D. E.; Savage, M. E.; Schmit, Paul; Smith, I. C.; Styron, Jedediah; Porter, J. L.; Jones, B.; Mattsson, Thomas R.; Peterson, Kyle; Rochau, Gregory A.; Sinars, Daniel Brian

doi:10.1103/physrevlett.125.155002

Cited by 77 publications

(46 citation statements)

References 42 publications

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“…For instance, in this work fuel pre-heating is intentionally not considered as it increases the thermal pressure of the hot-spot at the cost of reducing B-field compressibility. Pre-heating is otherwise essential in the MagLIF design to enhance the neutron yield [28]. Therefore, the proposed research is distinct -albeit complementary-to the current mini-MagLIF studies.…”

Section: Magnetized Cylindrical Implosions On Omegamentioning

confidence: 97%

“…Due to fuel magnetization and pre-heating, MagLIF aims at nearadiabatic stable cylindrical compression with lower implosion velocity (∼ 100 km/s, instead of > 300 km/s) and lower convergence ratios than conventional ICF. MagLIF has shown promising results through different experimental campaigns by demonstrating thermonuclear neutron generation at fusion-relevant conditions, a high enough fuel magnetization for α-particles trapping [25][26][27] and reporting first performance scaling studies [28].…”

Section: Introductionmentioning

confidence: 99%

“…Magnetized plasmas are thought to exhibit complex behavior in the electron population and, above resistive-MHD, extended-MHD additionally accounts for temperature-gradientdriven transport -such as the Nernst term moving magnetic fields down electron temperature gradients-and electric-current-driven transport -such as the Hall term moving magnetic fields with the flow of charge-. The Nernst term, in particular, is of great interest to the scientific community, with importance in a broad range of experiments [16,28,[35][36][37] with expectations of plasma demagnetization [23,[38][39][40][41]. Even with its wide applicability, Nernst advection of magnetic field is yet to be directly measured.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Exploring extreme magnetization phenomena in directly-driven imploding cylindrical targets

Walsh,

Florido,

Bailly-Grandvaux

et al. 2021

Preprint

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Section: Magnetized Cylindrical Implosions On Omegamentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Exploring extreme magnetization phenomena in directly-driven imploding cylindrical targets

Walsh,

Florido,

Bailly-Grandvaux

et al. 2021

Preprint

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“…There are many MIF schemes currently operating, such as the MagLIF experiment at Sandia National Laboratories 18 , where pulsed power is used to implode a beryllium liner onto a laser pre-heated and axially pre-magnetised column of deuterium. MagLIF has observed neutron yields of more than 10 13 , but flux compression has been hampered by the Nernst effect 19,20 . Recent "mini-MagLIF" experiments on OMEGA have attempted to use laser-driven cylindrical implosions to assist with this effort 21 .…”

Section: Introductionmentioning

confidence: 99%

Self-similar solutions for resistive diffusion, Ohmic heating and Ettingshausen effects in plasmas of arbitrary $β$

Farrow,

Kagan,

Chittenden

2021

Preprint

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Magneto-inertial fusion (MIF) approaches, such as the MagLIF experiment, use magnetic fields in dense plasma to suppress cross-field thermal conduction, attempting to reduce heat losses and trap alpha particles to achieve ignition. However, the magnetic field can introduce other transport effects, some of which are deleterious. An understanding of these processes is thus crucial for accurate modelling of MIF. We generalise past work exploiting self-similar solutions to describe transport processes in planar geometry and compare the model to the radiation-magnetohydrodynamics code Chimera. We solve the 1D extended magnetohydrodynamic (MHD) equations under pressure balance, making no assumptions about the ratio of magnetic and thermal pressures in the plasma. The resulting ordinary differential equation (ODE) boundary value problem is solved using a shooting method, combining an implicit ODE solver and a Newton-Raphson root finder. We show that the Nernst effect dominates over resistive diffusion in high β plasma, but its significance is reduced as the β decreases. On the other hand, we find that Ettingshausen and Ohmic heating effects are dominant in low β plasma, and can be observable in even order unity β plasma, though in the presence of a strong temperature gradient heat conduction remains dominant. We then present a test problem for the Ohmic heating and Ettingshausen effects which will be useful to validate codes modelling these effects. We also observe that the Ettingshausen effect plays a role in preventing temperature separation when Ohmic heating is strong. Neglecting this term may lead to overestimates for the electron temperature at a vacuum-plasma interface, such as at the edge of a z-pinch. The model developed can be used to provide test problems with arbitrary boundary conditions for magnetohydrodynamics codes, with the ability to freely switch on terms to compare their individual implementations.

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“…This leads to difficulty in defining the critical Mach number (due to the lack of downstream thermodynamic equilibrium) and determining the plasma resistivity. Recent progress in magneto-inertial fusion [13][14][15][16], has stimulated renewed interest in MHD shocks propagating through dense, collision-dominated plasmas. In particular, recent experiments studying the implosion of magnetised inertial confinement fusion capsules have shown an increased yield and anisotropic shock structure [17,18].…”

mentioning

confidence: 99%

Perpendicular subcritical shock structure in a collisional plasma experiment

Russell¹,

C.²,

Carroll-Nellenback³

et al. 2022

Preprint

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We present a study of perpendicular subcritical shocks in a collisional laboratory plasma. Shocks are produced by placing obstacles into the super-magnetosonic outflow from an inverse wire array z-pinch. We demonstrate the existence of subcritical shocks in this regime and find that secondary shocks form in the downstream. Detailed measurements of the subcritical shock structure confirm the absence of a hydrodynamic jump. We calculate the classical (Spitzer) resistive diffusion length and show that it is approximately equal to the shock width. We measure little heating across the shock (< 10% of the ion kinetic energy) which is consistent with an absence of viscous dissipation.

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Performance Scaling in Magnetized Liner Inertial Fusion Experiments

Cited by 77 publications

References 42 publications

Exploring extreme magnetization phenomena in directly-driven imploding cylindrical targets

Exploring extreme magnetization phenomena in directly-driven imploding cylindrical targets

Self-similar solutions for resistive diffusion, Ohmic heating and Ettingshausen effects in plasmas of arbitrary $β$

Perpendicular subcritical shock structure in a collisional plasma experiment

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