X射线背光成像的实现
刘利锋, 肖沙里, 钱家渝. X射线背光成像的实现[J]. 应用光学, 2017, 38(3): 381.
Liu Lifeng, Xiao Shali, Qian Jiayu. Realization of X-ray backlight imaging[J]. Journal of Applied Optics, 2017, 38(3): 381.
[1] 王淦昌, 袁之尚.惯性约束核聚变[M].北京: 原子能出版社, 2005: 188-199.
Wang Ganchang,Yuan Zhishang. Inertial confinement fusion[M].Beijing: Atomic Energy Press, 2005: 188-199.
[2] Rosmeja O N, Wiesera J, Geissela M, et al. X-ray spectromicroscopy of fast heavy ions and target radiation[J].Nuclear Instruments and Methods in Physics Research A,2002 , 495(8) : 29-39.
[3] Sorge S, Wierting A, Roepke G, et al. Diagnostics of a laser-induced dense plasma by hydrogen-like carbon spectra[J]. Phys. B,2000,33(16): 2983-3000.
[4] Regan S P , Delettrez J A , Jaanimagi P A , et al. Characterization of direct-drive-implosion core conditions on OMEGA with time-resolved Ar K-shell spectroscopy[J]. 2001. Physics of Plasmas, 2002, 9(4): 1357-1365.
[5] Bitter M, Hill K W, Stratton B, et al. Spatially resolved spectra from a new x-ray imaging crystal spectrometer for measurements of ion and electron temperature profiles (invited)[J]. Review of Scientific Instruments, 2004, 75(10): 3660-3665.
[7] 刘利锋,肖沙里,钱家渝.球面晶体背光成像系统模拟[J]. 应用光学,2016,37(3): 332-336.
[8] Bennett G R, Sinars D B, Wenger D F, et al. High-brightness, high-spatial-resolution, 6.151 keV X-ray imaging of inertial confinement fusion capsule implosion and complex hydrodynamics experiments on Sandia’s Z accelerator(invited)[J]. Review of Scientific Instruments,2006,77(10): 10E322.
[9] Aglitskiy Y, Lehecka T, Obenschain S,et al . High-resolution monochromatic x-ray imaging system based on spherically bent crystals[J]. Applied Optics,1998,37(22): 5253-5261.
[10] Aglitskiy Y, Lehecka T, Obenschain S, et al. X-ray crystal imagers for inertial confinement fusion experiments[J]. Review of Scientific Instruments, 1999,70(1): 530-535.
[11] Sinars D B, Bennett G R, Wenger D F, et al. Monochromatic X-ray imaging experiments on the Sandia National Laboratories Z facility (invited)[J]. Review of Scientific Instruments,2004,75(10): 3672-3677.
[12] Sinars D B, Bennett G R, Wenger D F, et al. Evaluation of bent-crystal X-ray backlighting and microscopy techniques for the Sandia Z machine[J]. Applied Optics, 2003,42(19): 4059-4071.
[13] Zhang X M, Zheng W G, Wei X F,et al. Preliminary experimental results of shenguang III technical integration experiment Line[J]. SPIE, 2005,5627: 6-12.
[14] Journel L, Khoury L E, Marin T, et al. Performances of a bent-crystal spectrometer adapted to resonant x-ray emission measurements on gas-phase samples [J]. Review of Scientific Instruments,2009,80(09): 093105.
[15] Marshall F. J , Allen M. M, Knauer J. P, et al . A high-resolution X-ray microscope for laser-driven planar-foil experiments[J]. Physics of Plasmas,1998 ,5 (4) : 1118-1124.
[16] Knapp P. F, Greenly J. B, Gourdain P. A, et al. Quasimonochromatic X-ray backlighting on the cornell beam research accelerator(COBRA) pulsed power generator[J].Review of Scientific Instrument, 2010,81(10): 10E501.
刘利锋, 肖沙里, 钱家渝. X射线背光成像的实现[J]. 应用光学, 2017, 38(3): 381. Liu Lifeng, Xiao Shali, Qian Jiayu. Realization of X-ray backlight imaging[J]. Journal of Applied Optics, 2017, 38(3): 381.