The inadequacy of a magnetohydrodynamic approach to the Biermann battery

Ridgers, C. P.; Arran, Christopher; Bissell, J. J.; Kingham, R. J.

doi:10.1098/rsta.2020.0017

Cited by 11 publications

(5 citation statements)

References 37 publications

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“…A further consideration is the applicability of the XMHD model itself. Kinetic studies suggest that Biermann magnetic field generation is strongly reduced for conditions with non-local heat flux 37 . Our model also needs a more rigorous assessment against a database of various XMHD simulations, preferably including burn and perturbations in three-dimensions.…”

Section: Discussionmentioning

confidence: 99%

“…Additional uncertainty arises from the validity of the XMHD and Biermann models themselves. For steep temperature gradients, Biermann generation is heavily reduced 37,38 . This kinetic reduction could be important in ICF, especially earlier on in the implosion and at the higher temperatures typical of ignition.…”

Section: Magnetization Model and The Static Ignition Thresholdmentioning

confidence: 99%

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Role of self-generated magnetic fields in the inertial fusion ignition threshold

Sadler,

Walsh,

Zhou

et al. 2022

Preprint

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Magnetic fields spontaneously grow at unstable interfaces around hot-spot asymmetries during inertial confinement fusion implosions. Although difficult to measure, theoretical considerations and numerical simulations predict field strengths exceeding 5 kT in current national ignition facility experiments. Magnetic confinement of electrons then reduces the hot-spot heat loss by > 5%. We demonstrate this via magnetic post-processing of two-dimensional xRAGE hydrodynamic simulation data at bang time. We then derive a model for the self-magnetization, finding that it varies with the square of the stagnation temperature and inversely with the areal density. The self-magnetized Lawson analysis then gives a slightly reduced ignition threshold. Time dependent hot-spot energy balance models corroborate this finding, with the magnetic field quadrupling the fusion yield for near threshold parameters. The inclusion of magnetized multi-dimensional fluid instabilities could further alter the ignition threshold, and will be the subject of future work.

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Section: Discussionmentioning

confidence: 99%

Section: Magnetization Model and The Static Ignition Thresholdmentioning

confidence: 99%

Role of self-generated magnetic fields in the inertial fusion ignition threshold

Sadler,

Walsh,

Zhou

et al. 2022

Preprint

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“…tend to produces ion-acoustic waves in their wake [76][77][78] . Thus, the same shocked systems that are predicted to produce magnetic fields in astrophysics via the Biermann battery [79][80][81][82][83][84][85][86] , such as those around super-nova remnants 82,83 , could produce magnetic fields via IAWdriven currents, providing an alternate possible mechanism for the origin of cosmological seed magnetic fields.…”

Section: Mechanism Of Magnetogenesis By Ion-acoustic Wavesmentioning

confidence: 99%

Momentum Conservation in Current Drive and Alpha-Channeling-Mediated Rotation Drive

Ochs,

Fisch

2022

Preprint

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Alpha channeling uses waves to extract hot ash from a fusion plasma, while transferring energy from the ash to the wave. Intriguingly, it has been proposed that the extraction of this charged ash could create a radial electric field, efficiently driving E × B rotation. However, existing theories ignore the response of the nonresonant particles, which play a critical role in enforcing momentum conservation in quasilinear theory. Because cross-field charge transport and momentum conservation are fundamentally linked, this non-consistency throws the whole effect into question.Here, we review recent developments that have largely resolved this question of rotation drive by alpha channeling. We build a simple, general, self-consistent quasilinear theory for electrostatic waves, applicable to classic examples such as the bump-on-tail instability. As an immediate consequence, we show how waves can drive currents in the absence of momentum injection even in a collisionless plasma. To apply this theory to the problem of ash extraction and rotation drive, we develop the first linear theory able to capture the alpha channeling process. The resulting momentum-conserving linear-quasilinear theory reveals a fundamental difference between the reaction of nonresonant particles to plane waves that grow in time, versus steady-state waves that have nonuniform spatial structure, allowing rotation drive in the latter case while precluding it in the former. This difference can be understood through two conservation laws, which demonstrate the local and global momentum conservation of the theory. Finally, we show how the oscillation-center theories often obscure the time-dependent nonresonant recoil, but ultimately lead to similar results. I. BACKGROUND AND INTRODUCTION

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“…This asymmetry does not significantly affect the results presented here, but 3-D simulations are required to reproduce the measured neutron yields, and are therefore used for these analysis as well. Simulations of the unmagnetized shot were run with different flux limiters (f = 0.15 and f = 0.05, commonly used values for high and low heat flux, respectively [15]) to test the extent to which the flux limiter affects the Biermann battery mechanism by modifying the electron temperature gradients [16]. All other simulations were run with a flux limiter of f = 0.15.…”

Section: Simulationmentioning

confidence: 99%

Diagnosing Magnetic Fields in Cylindrical Implosions with Oblique Proton Radiography

Heuer,

Leal,

Davies

et al. 2022

Preprint

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The inadequacy of a magnetohydrodynamic approach to the Biermann battery

Cited by 11 publications

References 37 publications

Role of self-generated magnetic fields in the inertial fusion ignition threshold

Role of self-generated magnetic fields in the inertial fusion ignition threshold

Momentum Conservation in Current Drive and Alpha-Channeling-Mediated Rotation Drive

Diagnosing Magnetic Fields in Cylindrical Implosions with Oblique Proton Radiography

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