Influence of laser induced hot electrons on the threshold for shock ignition of fusion reactions

Colaïtis, A.; Ribeyre, X.; Bel, E. Le; Duchateau, Guillaume; Nicolaï, Ph.; Tikhonchuk, V. T.

doi:10.1063/1.4958808

Cited by 23 publications

(23 citation statements)

References 39 publications

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“…However, the SBS threshold is below the SRS one, around 2 to 5x10 14 W/cm 2 , that qualitatively explain the SBS prevalence over SRS, in agreement with the data. Comparing now these thresholds in plasma profiles expected from targets designed for the direct-drive scheme for LMJ [28], we note that the electron density scalelength is typically one-third smaller in our experiments, thus the SRS threshold is expected to be one third lower as well for LMJ. On the contrary, both the electron temperature T e and the expansion velocity scale-length L V = [1/V ΔV/Δz] -1 increase by a factor of two in the LMJ design, as calculated by the CHIC code.…”

Section: Resultsmentioning

confidence: 56%

Shock generation comparison with planar and hemispherical targets in shock ignition relevant experiment

et al. 2017

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We performed an experiment on the "Ligne d'Intégration Laser" facility to produce strong shocks with plasma conditions relevant for the Shock Ignition approach to Inertial Confinement Fusion. Two kinds of target have been used: planar and hemispherical. We observe an increase of the shock velocity in hemispherical geometry, which entails a fairly planar shock despite the Gaussian focal spot. Numerical results reproduce in the successful way the shock dynamics in the two cases, indicating, for laser intensities around 1.5×10 15 W/cm 2 at 3ω, an ablation pressure of (90 ± 20) Mbar and (120 ± 20) Mbar in planar and hemispherical geometry respectively. I.

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Section: Resultsmentioning

confidence: 56%

Shock generation comparison with planar and hemispherical targets in shock ignition relevant experiment

et al. 2017

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“…The CHIC simulations show only a minor increase in ablation pressure (less than 10%) and a strong increase in shock pressure resulting from hot electrons. The target preheat is an undesirable issue in the context of shock ignition since a shock of a small strength is much less ecient in the fuel heating of the central spot and hot-electron preheat during the ignitor spike may lead to hot-spot mass increase because of inner-shell ablation [28]. These problems may be mitigated by designing a target with a larger areal density.…”

Section: Discussionmentioning

confidence: 99%

The role of hot electrons in the dynamics of a laser-driven strong converging shock

et al. 2017

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Experiments on strong shock excitation in spherical plastic targets conducted at the Omega Laser Facility are interpreted with the radiationhydrodynamics code CHIC to account for parametric instabilities excitation and hot-electron generation. The eects of hot electrons on the shock-pressure amplication and upstream preheat are analyzed. It is demonstrated that both eects contribute to an increase in the shock velocity. Comparison of the measured laser reectivity and shock ash time with numerical simulations make it possible to reconstitute the time history of the ablation and shock pressures. Consequences of this analysis for the shock-ignition target design are discussed.2

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“…6(b). Although the hot electron preheat could increase the shock pressure, it also decreases the shock strength by raising the local sound velocity; 15,17 consequently, a smaller peak areal density (0:191 g=cm 2 ) is achieved compared with that (0:238 g=cm 2 ) in the case without preheat (see Fig. 7), corresponding to a decrease by 19.8% (or 0:047 g=cm 2 ).…”

Section: -6mentioning

confidence: 99%

“…hcos hi is the angular moments of the hot electron distribution function, which is introduced due to the scattering effect. 16 Generally, the LPI produced hot electrons have a large initial divergence angle, 11,15,17 which means that they deposit more quickly along the target radius than a wellcollimated electron beam does. To take into account this quick energy deposition, we introduce a parameter, g SP (>1), in our model.…”

Section: A Preheat Modulementioning

confidence: 99%

Confirmation of hot electron preheat with a Cu foam sphere on GEKKO-LFEX laser facility

et al. 2017

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Experiments with a solid Cu foam ($1.3 g/cm 3) sphere coated by a 20 lm CH ablator are performed on the GEKKO-LFEX laser facility to study the effect of hot electron preheat on the implosion performance. When the target is imploded by the GEKKO lasers ($1.2 Â 10 15 W/cm 2 in peak intensity), plenty of hot electrons are measured through the induced Cu Ka emission, indicating that the target could suffer strong preheat. This suffering of preheat is confirmed by the temporal evolution of the target self-emission, which is well reproduced by a 2D cylindrically symmetric radiative hydrodynamic code (FLASH) when a module handling the hot electron preheat is coupled. The results given by this benchmarked code indicate that, in the typical experiments with a small ($200 lm in diameter) solid sphere target conducted on the GEKKO-LFEX laser facility, the hot electron preheat greatly degrades the implosion performance, reducing the peak areal densities of a Cu foam sphere and a CD sphere by $20%

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Influence of laser induced hot electrons on the threshold for shock ignition of fusion reactions

Cited by 23 publications

References 39 publications

Shock generation comparison with planar and hemispherical targets in shock ignition relevant experiment

Shock generation comparison with planar and hemispherical targets in shock ignition relevant experiment

The role of hot electrons in the dynamics of a laser-driven strong converging shock

Confirmation of hot electron preheat with a Cu foam sphere on GEKKO-LFEX laser facility

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