[1] [1] PARK H S, CHAMBERS D M, CHUNG H K, et al. High-energy K radiography using high-intensity, short-pulse lasers[J]. Physics of Plasmas, 2006,13(5): 056309.

[2] [2] DERESSGUIER T, PRUDHOMME G, ROLAND C, et al. Picosecond X-ray radiography of microjets expanding from laser shock-loaded grooves[J]. Journal of Applied Physics, 2018,124(6): 065106.

[3] [3] PRUDHOMME G, DERESSGUIER T, ROLAND C, et al. Velocity and mass density of the ejecta produced from sinusoidal grooves in laser shock-loaded tin[J]. Journal of Applied Physics, 2020,128(15): 155903.

[4] [4] TOMMASINI R, HATCHETT S P, HEY D S, et al. Development of compton radiography of inertial confinement fusion implosions[J]. Physics of Plasmas, 2011,18(5): 056309.

[5] [5] PARK H S, MADDOX B, GIRALDEZ E, et al. High-resolution 17—75 keV backlighters for high energy density experiments[J]. Physics of Plasmas, 2008,15(7): 3048.

[8] [8] POY A, HULIN S, BAILLY-GRANDVAUX M, et al. Physics of giant electromagnetic pulse generation in short-pulse laser experiments[J]. Physical Review E, 2015,91(4): 043106.

[9] [9] HEGELICH M, KARSCH S, PRETZLER G, et al. MeV ion jets from short-pulse-laser interaction with thin foils[J]. Physical Review Letters, 2002,89(8): 085002.

[10] [10] SAWADA H, DAYKIN T S, HUTCHINSON T M, et al. Development of broadband X-ray radiography for diagnosing magnetically driven cylindrically compressed matter[J]. Physics of Plasmas, 2019,26(8): 083104.

[11] [11] BRAMBRINK E, BATON S, KOENIG M, et al. Short-pulse laser-driven X-ray radiography[J]. High Power Laser Science and Engineering, 2016,4(3): 101-105.

[12] [12] FAENOV A Y, PIKUZ T A, MABEY P, et al. Advanced high resolution X-ray diagnostic for HEDP experiments[J]. Scientific Reports, 2018,8(1): 16407.

[15] [15] TOMMASINI R, MACPHEE A, HEY D, et al. Development of backlighting sources for a compton radiography diagnostic of inertial confinement fusion targets (invited)[J]. Review of Scientific Instruments, 2008,79: 10E901.

[17] [17] ARMSTRONG C D, BRENNER C M, JONES C, et al. Bremsstrahlung emission from high power laser interactions with constrained targets for industrial radiography[J]. High Power Laser Science and Engineering, 2019,7(2): 27-33.

[18] [18] BRAMBRINK E, WEI H G, BARBREL B, et al. X-ray source studies for radiography of dense matter[J]. Physics of Plasmas, 2009,16(3): 033101.

[19] [19] TOMMASINI R, BAILEY C, BRADLEY D K, et al. Short pulse, high resolution, backlighters for point projection high-energy radiography at the national ignition facility[J]. Physics of Plasmas, 2017,24(5): 053104.

[20] [20] LI M T, HU G Y, HUANG L G, et al. Influence of a low-Z thin substrate on a microwire hard X-ray source driven by a picosecond laser pulse for point-projection X-ray radiography[J]. Physics of Plasmas, 2020,27(1): 123107.

[21] [21] ARMSTRONG C D, BRENNER C M, ZEMAITYTE E, et al. Bremsstrahlung emission profile from intense laser-solid interactions as a function of laser focal spot size[J]. Plasma Physics and Controlled Fusion, 2019, 61(3): 034001.

[22] [22] NAGEL S R, CHEN H, PARK J, et al. Two-dimensional time-resolved ultra-high speed imaging of K-alpha emission from short-pulse-laser interactions to observe electron recirculation[J]. Applied Physics Letters, 2017,110(14): 144102.

[28] [28] GAMBACCINI M, CARDARELLI P, TAIBI A, et al. Measurement of focal spot size in a 5.5MeV linac[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2011,269(10): 1157-1165.

[29] [29] WILKIN T, DON S, KEITH L C. Analysis of electric field screening by the proximity of two knife-edge field emitters[J]. Journal of Applied Physics, 2011,110(3): 034905.

[30] [30] KULPE S, DIEROLF M, GNTHER B, et al. Dynamic K-edge subtraction fluoroscopy at a compact inverse-compton synchrotron X-ray source[J]. Scientific Reports, 2020,10(1): 9612.