Status of the development of ignition capsules in the U.S. effort to 
achieve thermonuclear ignition on the national ignition facility

Nobile, A.; Nikroo, A.; Cook, Robert; Cooley, J. C.; Alexander, David; Hackenberg, Robert E.; Necker, C.T.; Dickerson, Robert M.; J, Kilkenny,; Bernat, T. P.; Chen, K.C.; Xu, Hongwei; Stephens, R. B.; Huang, H.; Haan, S. W.; Forsman, A.; Atherton, L. J.; Letts, Stephan A.; Bono, Matthew; Wilson, D. C.

doi:10.1017/s0263034606060757

Cited by 28 publications

(9 citation statements)

References 6 publications

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“…It is proposed to use the method of a dynamic plasma phase plate (Voronich et al, 2001) for smoothing spatial intensity distribution of heating radiation on the target. The optical transparency of a plasma layer is an essential method of a dynamic plasma phase plate, which leads to the necessity of using the low density volume-structured media (Borisenko et al, 1994(Borisenko et al, , 2008Khalenkov et al, 2006;Moreau et al, 2009;Yu et al, 2009b) Volume-structured materials are considered as different functional elements in the inertial confinement fusion (ICF) targets (Dunne et al, 1995;Gus'kov & Rosanov, 1997;Bugrov et al, 1997Bugrov et al, , 1999aBugrov et al, , 1999bNazarov et al, 1999;Cook et al, 2008;Nobile et al, 2006). First of all, smoothing of a heating inhomogeneity and production of a steady compression of the ICF targets prove to be possible applications of those materials.…”

Section: Introductionmentioning

confidence: 99%

Aerogel foil plasma: Forward scattering, back scattering, and transmission of laser radiation

et al. 2010

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Experimental results obtained with "Kanal-2" facility under the study of powerful laser pulse interaction with the low density microstructure media are presented and discussed in this paper. Forward scattering, back scattering, and transmission of laser radiation by aerogel foil plasma have been investigated. The temporal, spectral, and energy characteristics of both the radiation scattering in the direction of heating radiation beam and the back scattering radiation were studied; the directional diagrams of forward and back scattering radiation were obtained for v 0 and 2v 0 frequencies. Analysis of intensity redistribution on the heating beam cross-section after passing through a polymer microstructure target was carried out.

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Section: Introductionmentioning

confidence: 99%

Aerogel foil plasma: Forward scattering, back scattering, and transmission of laser radiation

et al. 2010

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“…However, laser laboratories worldwide are participating in the effort to understand the details of beam matter interaction physics necessary to achieve the conditions of inertial fusion (Laska et al, 2006;Lontano et al, 2006;Borghesi et al, 2005;Schaumann et al, 2005). The scientific discussion for many years shows (Meyer-ter-Vehn et al, 1990;Funk et al, 1998) and it was confirmed here that the target design is a most crucial issue for the experimental facilities as well as for a future full scale driver (Nobile et al, 2006; …”

mentioning

confidence: 52%

Editorial from the Editor in Chief: Inertial Fusion Energy on the Horizon

2007

Laser Part. Beams

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“…A prism-raster focusing system provided large enough (7 Â 7 mm 2 ) square irradiation spot on a target with uniform intensity distribution to ensure initially planar SW generation. The moderate laser intensities q ¼ 0.1-1 GW/cm 2 and long pulse duration of 100 ns has distinguished our experiments from those performed at the ICF-scale huge powerful lasers with high intensities q ¼ 1-100 TW/cm 2 and nanosecond pulses (see, i.e., Kilkenny et al, 1994Kilkenny et al, , 2005Farley et al, 1999;Nobile et al, 2006;Aglitskiy et al, 2006).…”

Section: Liquid-filled Laser-driven Shock Tube Conceptmentioning

confidence: 91%

Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

et al. 2008

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The paper is devoted to research and development of a novel experimental technique-liquid-filled laser-driven shock tube (LST) for modeling of Rayleigh-Taylor (RT) and Richtmyer-Meshkov (RM) hydrodynamic instabilities development at the contact surface of two immiscible liquids under shock wave (SW) passage. 100-J, 100-ns KrF laser facility GARPUN has been used to irradiate some opaque liquids. A homogenizing focusing system combined multi-element prism raster and a lens to provide non-uniformity less than a few percents across a square 7 Â 7-mm spot, laser intensities being varied in the range of q ¼ 0.004-2 GW/cm 2 . Surface plasma blow-off produced a planar SW, which propagated into the liquid. SW amplitudes as high as 0.8 GPa weakly damping with increasing thickness were measured in dibutyl-phthalate (DBP), which volumetrically absorbed ultraviolet (UV) laser light. Nonlinear absorption coefficients and laser breakdown thresholds were measured for pure water and UV optical materials intended to confine plasma. Test bench experiments were performed to produce standing acoustic waves as initial perturbations at the interface between two immiscible liquids.

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Status of the development of ignition capsules in the U.S. effort to achieve thermonuclear ignition on the national ignition facility

Cited by 28 publications

References 6 publications

Aerogel foil plasma: Forward scattering, back scattering, and transmission of laser radiation

Aerogel foil plasma: Forward scattering, back scattering, and transmission of laser radiation

Editorial from the Editor in Chief: Inertial Fusion Energy on the Horizon

Planar shock waves in liquids produced by high-energy KrF laser: A technique for studying hydrodynamic instabilities

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