研究目的
Investigating the hohlraum energetics of two-entrance holes spherical hohlraum at the 100 kJ level laser facility, focusing on x-ray conversion efficiency and laser-plasma interaction effects.
研究成果
The x-ray conversion efficiency of the vacuum spherical hohlraum was found to be 85%–88% in 3 ns square pulses and 89%–93% in 3.6 ns shaped pulses, closely matching that of the two-LEH cylindrical hohlraum at the Shen-Guang and NIF facilities. The study also identified low levels of LPI effects in the spherical hohlraum, with significant increases in SRS only observed in shaped pulse shots with capsules.
研究不足
The study was limited by the laser beam configuration designed for 2-LEH cylindrical hohlraum, introducing large driven asymmetry and longer laser propagation length inside the hohlraum. The backscattered laser energy measurement had an uncertainty of ±25%, and the influence of ablated CH plasma on LPI was not fully explored.
1:Experimental Design and Method Selection:
The study involved two types of laser pulses (3 ns square and
2:6 ns shaped) to investigate energy coupling and LPI effects in a vacuum spherical hohlraum with/without a capsule. Sample Selection and Data Sources:
The hohlraum was designed with a radius of
3:8 mm and LEH radius of 6 mm, with/without a capsule. List of Experimental Equipment and Materials:
Included multi-angle x-ray diodes (FXRDs), Full Aperture Backscatter Station (FABS), Nearby Backscatter Station (NBS), and a streak camera for time-resolved spectrum measurement.
4:Experimental Procedures and Operational Workflow:
Laser beams were arranged at four cone-angles, and diagnostics focused on radiation flux, hot electron energy, x-ray radiography, and backscattered laser energy.
5:Data Analysis Methods:
The x-ray conversion efficiency was inferred based on the hohlraum power balance equation, and LPI effects were analyzed through backscattered laser energy and SRS spectrum.
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