High Power Laser and Particle Beams, Volume. 32, Issue 11, 112002(2020)
Progress in high time- and space-resolving diagnostic technique for laser-driven inertial confinement fusion
Fig. 1. Schematic diagram of all-optical diagnostic technology for single point pulse behavior measurement
Fig. 2. Typical measurement results of single pulse transient behavior
Fig. 3. Optical path diagram of high time-resolving all optical scanning diagnostic technology based on photorefractive effect
Fig. 4. Schematic diagram of all-optical framing imaging diagnostic technique
Fig. 5. Time response data of all-optical frame imaging diagnostic converter
Fig. 7. (a) Energy responses of the KB microscope and (b) the reflectivity spatial distribution of 6 keV X-ray
Fig. 8. Backlit image of the four-phase mesh and the analysis of the spatial resolution of full reflection KB imaging system
Fig. 9. Measured hot spot images in the exploding pusher target and the indirectly driven implosions
Fig. 10. Optics design of the multi-layer coated quasi-monenergistic response KB microscope
Fig. 11. Throughout response of the multi-layer coated KB microscope (a) and the backlit image of an 1000# Ni mesh (b) and the hot spot image in the hohlraum driven implosion (c)
Fig. 12. Schematic diagram of imaging principle for each imaging dimension of KBA micro imaging system
Fig. 13. (a)structural diagram of dual channel KBA-KB imaging system;(b)the backlit image of a 600# Au mesh
Fig. 14. (a) Structural diagram of the AKB imaging system;(b) optics diagram of the AKB imaging in sagittal and tangential directions
Fig. 15. (a) Spherically bent crystal samples fabricated by LFRC and (b) the test result at laser facility
Fig. 16. Diagram of the monochromatic imaging system with spherical crystal installed on the DIM
Fig. 17. 2D radiography applications of the monochromatic imaging system with spherical crystal
Fig. 18. Implosion trajectory measurement image by the monochromatic imaging system with spherical crystal
Fig. 19. (a)Single line-of-sight (SLOS) X-ray imager and(b) schematic diagram of photoelectron expanding principle
Fig. 20. (a)Schematic diagram of four end fed cathode structure and(b)four channel composite waveforms
Fig. 21. (a)Photo of drift tube of double lens short magnetic focusing lens and(b)image of adjusting the current of two magnetic lenses to obtain 10 lp/mm resolution
Fig. 23. Designed biconic-shaped geometric aperture parameters and the spatial resolution contributed by the aperture
Fig. 24. Measured line-spread function of the neutron image detector
Common techniques for high temporal resolution purposes
国际上常见的高时间分辨的几个技术状态比较
Common techniques for high temporal resolution purposes
国际上常见的高时间分辨的几个技术状态比较
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Parameters of the reflective KB microscope
反射式宽能带KB显微成像系统光学参数
Parameters of the reflective KB microscope
反射式宽能带KB显微成像系统光学参数
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Parameters of the multi-layer coated quasi-monenergistic response KB microscope
多层膜单能响应KB显微成像系统光学参数
Parameters of the multi-layer coated quasi-monenergistic response KB microscope
多层膜单能响应KB显微成像系统光学参数
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Feng Wang, Xing Zhang, Yulong Li, Bolun Chen, Zhongjing Chen, Tao Xu, Xincheng Liu, Hang Zhao, Kuan Ren, Jiamin Yang, Shaoen Jiang, Baohan Zhang. Progress in high time- and space-resolving diagnostic technique for laser-driven inertial confinement fusion[J]. High Power Laser and Particle Beams, 2020, 32(11): 112002
Category: Inertial Confinement Fusion Physics and Technology
Received: May. 19, 2020
Accepted: --
Published Online: Jan. 4, 2021
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