Suppression kinetic bursts in stimulated Raman scattering with an intensity-modulated broadband laser

Abstract

Laser plasma instability is one of the difficulties that plague inertial confinement fusion. As an effective tool for suppressing laser-plasma instabilities, broadband lasers have received a lot of attention in recent years. However, the nonlinear bursts of high-frequency instabilities, such as stimulated Raman scattering driven by broadband lasers in the kinetic regime, make the suppression effect less than expected. In this paper, a broadband laser model with intensity modulation is proposed. By choosing an appropriate intensity modulation envelope, it is possible to interrupt the amplification process of backscattered light in strong pulses, reduce the probability of high-intensity pulses inducing intense bursts, and drastically reduce the fraction of backscattered light and hot electron yield. Numerical simulations showed that the intensity-modulated laser has a good ability to suppress stimulated Raman scattering. For a broadband laser with an average power of 1.0 × 10¹⁵ <i>W/cm</i>² and a bandwidth of 0.6%, the reflectivity decreases by an order of magnitude and the fraction of hot electron energy above 20 <i>keV</i> decreases from 7.34% to 0.31% using the intensity modulation technique. The above results confirm the feasibility of using the intensity-modulated broadband laser to suppress the high-frequency instability and are expected to provide a reference for the design of subsequent broadband laser-driven fusion experiments.