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On the change in Inertial Confinement Fusion Implosions upon using an ab initio multiphase DT equation of state

Improving the description of the equation of state (EoS) of deuterium-tritium (DT) has recently been shown to change significantly the gain of an Inertial Confinement Fusion (ICF) target (Hu et al., PRL 104, 235003 (2010)). We use here an advanced multi-phase equation of state (EoS), based on ab initio calculations, to perform a full optimization of the laser pulse shape with hydrodynamic simulations starting from 19 K in DT ice. The thermonuclear gain is shown to be a robust estimate over possible uncertainties of the EoS. Two different target designs are discussed, for shock ignition and self-ignition. In the first case, the areal density and thermonuclear energy can be recovered by slightly increasing the laser energy. In the second case, a lower in-flight adiabat is needed, leading to a significant delay (3ns) in the shock timing of the implosion.

preprint2011arXivOpen access
Laurent CaillabetBenoit CanaudGwenaël SalinStéphane MazevetPaul Loubeyre
physics.plasm-ph
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Laurent CaillabetBenoit CanaudGwenaël SalinStéphane MazevetPaul Loubeyre

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