Kinetic mix mechanisms in shock-driven inertial confinement fusion implosions | Zendy

H. G. Rinderknecht | Zendy; H. Sio | Zendy; C. K. Li | Zendy; N. M. Hoffman | Zendy; A. B. Zylstra | Zendy; M. J. Rosenberg | Zendy; J. A. Frenje | Zendy; M. Gatu Johnson | Zendy; F.H. Séguin | Zendy; R. D. Petrasso | Zendy; R. Betti | Zendy; V. Yu. Glebov | Zendy; D. D. Meyerhofer | Zendy; T. C. Sangster | Zendy; W. Seka | Zendy; C. Stöeckl | Zendy; Grigory Kagan | Zendy; Kim Molvig | Zendy; C. Bellei | Zendy; Peter Amendt | Zendy; O. L. Landen | Zendy; J. R. Rygg | Zendy; V. A. Smalyuk | Zendy; S. C. Wilks | Zendy; A. Greenwood | Zendy; A. Nikroo | Zendy

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Kinetic mix mechanisms in shock-driven inertial confinement fusion implosions

Author(s) -

H. G. Rinderknecht,

H. Sio,

C. K. Li,

N. M. Hoffman,

A. B. Zylstra,

M. J. Rosenberg,

J. A. Frenje,

M. Gatu Johnson,

F.H. Séguin,

R. D. Petrasso,

R. Betti,

V. Yu. Glebov,

D. D. Meyerhofer,

T. C. Sangster,

W. Seka,

C. Stöeckl,

Grigory Kagan,

Kim Molvig,

C. Bellei,

Peter Amendt,

O. L. Landen,

J. R. Rygg,

V. A. Smalyuk,

S. C. Wilks,

A. Greenwood,

A. Nikroo

Publication year - 2014

Publication title -

physics of plasmas

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.75

H-Index - 160

eISSN - 1089-7674

pISSN - 1070-664X

DOI - 10.1063/1.4876615

Subject(s) - physics , kinetic energy , deuterium , inertial confinement fusion , instability , shock (circulatory) , plasma , acceleration , diffusion , fusion , ion , atomic physics , nuclear physics , mechanics , thermodynamics , classical mechanics , medicine , linguistics , philosophy , quantum mechanics

Shock-driven implosions of thin-shell capsules, or “exploding pushers,” generate low-density, high-temperature plasmas in which hydrodynamic instability growth is negligible and kinetic effects can play an important role. Data from implosions of thin deuterated-plastic shells with hydroequivalent D3He gas fills ranging from pure deuterium to pure 3He [H. G. Rinderknecht et al., Phys. Rev. Lett. 112, 135001 (2014)] were obtained to evaluate non-hydrodynamic fuel-shell mix mechanisms. Simulations of the experiments including reduced ion kinetic models support ion diffusion as an explanation for these data. Several additional kinetic mechanisms are investigated and compared to the data to determine which are important in the experiments. Shock acceleration of shell deuterons is estimated to introduce mix less than or comparable to the amount required to explain the data. Beam-target mechanisms are found to produce yields at most an order of magnitude less than the observations.

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