[1]
|
Luther-Davies B, Perry A, Nugent K A. K Alpha emission measurements and superthermal electron transport in layered laser-irradiated disk targets[J]. Physical Review A, 1987, 35(10):4306-4313. |
[2]
|
Widmann K, Beiersdorfer P, Brown G V, et al. A high-resolution transmission-type X-ray spectrometer designed for observation of the Kalpha transitions of highly charged highZ ions[J]. Review of Scientific Instruments, 1997, 68(1):1087-1090. |
[3]
|
Okano Yasuaki, Hironaka Yoichiro, Nakamura Kazutaka G, et al. Energy distribution of electrons ejected from a copper target in a femtosecond laser field of 1017 W/cm2[J]. Journal of Applied Physics, 2004, 95(5):2278-2282. |
[4]
|
Wharton K B, Hatchett S P, Wilks S C, et al, Experimental measurements of hot electrons generated by ultraintense ( 1019 W/cm2) laser-plasma interactions on solid-density targets[J]. Physical Review Letters, 1998, 81(4):822-825. |
[5]
|
Beg F N, Bell A R, Dangor A E, et al, A study of picosecond laser-solid interactions up to 1019 W/cm2[J]. Physics of Plasmas, 1997, 4(2):447-457. |
[6]
|
Strickland D, Mourou G. Compression of amplified chirped optical pulses[J]. Optics Communications, 1985, 56(3):219-221. |
[7]
|
Yanovsky V, Chvykov V, Kalinchenko G, et al, Ultra-high intensity-300-Tw laser at 0.1 Hz repetition rate[J]. Optics Express, 2008, 16(3):2109-2114. |
[8]
|
Li Xiaoya, Wang Jiaxiang, Zhu Wenjun, et al, Enhanced inner-shell X-ray emission by femtosecond-laser irradiation of solid cone targets[J]. Physical Review E, 2011, 83(6):046404. |
[9]
|
Jonathan Workman, James R Fincke, George A Kyrala, et al. Uniform large-area x-ray imaging at 9 keV using a backlit pinhole[J]. Applied Optics, 2004, 44(6):859. |
[10]
|
Chen L M, Kando M, Xu M H, et al. Study of X-ray emission enhancement via a high-contrast femtosecond Laser interacting with a solid foil[J]. Physical Review Letters,2008, 100(4):045004. |
[11]
|
Mao J Y, Chen L M, Ge X L, et al. Spectrally peaked electron beams produced via surface guiding and acceleration in femtosecond laser-solid interactions[J]. Physical Review E, 2012, 85:025401. |
[12]
|
Tian Ye, Wang Wentao, Wang Cheng, et al. Experimental study of K-shell X-ray emission generated from nanowire target irradiated by relativistic laser pulses[J]. Chinese Optics Letters, 2013, 11(3):033501. |
[13]
|
Rajeev P P, Taneja P, Ayyub P, et al. Metal nanoplasmas as bright sources of hard x-ray pulses[J]. Physical Review Letters, 2003, 90(11):115002. |
[14]
|
Sudipta mondal, Indrani Chakraborty, Saima Ahmad, et al. Highly enhanced hard x-ray emission from oriented metal nanorod arrays excited by intense femtosecond laser pulses[J]. Physical Review B, 2011, 83(5):035408. |
[15]
|
Niu Gao, Tan Xiulan, Han Shangjun, et al. Structure and performance of Cu nanowire array target for intense radiation source[J]. High Power Laser and Particle Beams, 2011, 23(3):681-684. (In Chinese) |
[16]
|
Shang Wanli, Wei Huiyue, Li Zhichao, et al. Instantaneous X -Ray radiation energy from laser produced polystyrene plasmas for shock ignition conditions[J]. Physics of Plasmas, 2013, 20(10):102702. |
[17]
|
Xiong Yong. Conversion efficiencies of ultra-short ultra-intensity laser to ultra hot based on Ka X -ray electron[D]. Mianyang:Chinese Academy of Engineering Physics, 2008:90-92. (in Chinese) |
[18]
|
Reich Ch, Gibbon P, Uschmann I, rster E. Yield optimization and time structure of femtosecond laser plasma K sources[J]. Physical Review Letters, 2000, 84(21):4846-4849. |