Experimental study on ablative stabilization of Rayleigh-Taylor instability of laser-irradiated targets

Hydrodynamic instabilities are key issues of the physics of inertial confinement fusion (ICF) targets. Among the instabilities, Rayleigh-Taylor (RT) instability is the most important because it gives the largest growth factor in the ICF targets. Perturbations on the laser irradiated surface grow exponentially, but the growth rate is reduced by ablation flow. The growth rate gamma is written as Takabe-Betti formula: gamma = (kg/(1+kL))(1/2). -betakm/rho(a), where k is wave number of the perturbation, g is acceleration, L is density scale-length, beta is a coefficient, m is mass ablation rate per unit surface, and rho(a), is density at the ablation front. We experimentally measured all the parameters in the formula for polystyrene (CH) targets. Experiments were done on the RIPER laser facility at Institute of Laser Engineering, Osaka University. We found that the beta value in the formula is similar to 1.7, which is in good agreements with the theoretical prediction, whereas the beta for certain perturbation wavelengths are larger than the prediction. This disagreement between the experiment and the theory is mainly due to the deformation of the cutoff surface, which is created by non-uniform ablation flow from the ablation surface. We also found that high-Z doped plastic targets have multiablation structure, which can reduce the RT growth rate. When a low-Z target with high-Z dopant is irradiated by laser, radiation due to the high-Z dopant creates secondary ablation front deep inside the target. Since, the secondary ablation front is ablated by x-rays, the mass ablation rate is larger than the laser-irradiated ablation surface, that is, further reduction of the RT growth is expected. We measured the RT growth rate of Br-doped polystyrene targets. The experimental results indicate that of the CHBr targets show significantly small growth rate, which is very good news for the design of the ICF targets.