Resonance density range governs two-plasmon decay saturation and enables hot-electron prediction in inertial confinement fusion

Abstract

The saturation level of parametric instabilities critically determines their impact on fusion plasmas. We identify the resonance density range of two-plasmon decay as the critical parameter governing nonlinear saturation of ion density fluctuations and Langmuir waves, which drive hot-electron generation. Using this insight, we develop a predictive scaling model for the hot-electron energy fraction fhot that depends only on the laser intensity I, with plasma conditions encoded via plasma ablation theory. The model can work for various experimental configurations-requiring only two (I, fhot) data points to calibrate coefficients-and successfully reproduces results from prior OMEGA and OMEGA-EP experiments.