148 / 2026-03-31 17:35:46
Suppression of Laser Imprint induced Rayleigh-Taylor Instability via Preplasma Scale Length Controll
Laser imprint,Rayleigh-Taylor Instability,Preplasma,Electron thermal transport
Abstract Accepted
玉雪 张 / 中国工程物理研究院激光聚变研究中心
何翰林 王 / 中国工程物理研究院激光聚变研究中心
The laser direct-drive inertial confinement fusion (ICF) is one of the most promising routes to realize the high-gain fusion energy. However, laser imprints, arising from beam asymmetries and speckle structures, seed Rayleigh–Taylor instability (RTI) and severely limits its performance. In this work, we propose a novel approach to mitigate RTI by providing a pre-plasma with a hundred-micrometer-scale length prior to the main pulse reach the target surface. This configuration leverages nonlocal electron thermal transport to smooth laser-induced density perturbations. Using the radiation-hydrodynamic code FLASH coupled with the self-consistent Schurtz–Nicolai–Busquet (SNB) nonlocal transport model, we quantitatively investigate the influence of pre-plasma scale length on electron heat transport process and ablative RTI growth. Results show that increasing the pre-plasma scale length significantly extends the longitudinal conduction region and, more importantly, enables nonlocal thermal transport effects to smooth the instability seeds caused by laser imprinst, thereby effectively suppressing RTI growth. We further reveal a scaling relation between pre-plasma scale length and RTI mitigation, demonstrating that optimizing this parameter markedly improves implosion symmetry. This work provides a new design pathway for ICF targets and offers critical guidance for enhancing fusion gain.

 
Important Date
  • May 12

    2026

    Conference Date

  • Apr 15 2026

    Draft paper submission deadline

  • May 12 2026

    Registration deadline

Sponsored By
National Key Laboratory of Plasma Physics, Laser Fusion Research Center, China Academy of Engineering Physics
Xiamen University