[1] |
Skupsky S, Lee K. Uniformity of energy deposition for laser driven fusion [J]. J Appl Phys, 1983, 54(7): 3662-3671. |
[2] |
Desselberger M, Willi O, Savage M, et al. Measurement of the Rayleigh-Taylor instability in targets driven by optically smoothed laser beams [J]. Phys Rev Lett, 1990, 65(24): 2997-3000. |
[3] |
Hu S, Michel D T, Davis A K, et al. Understanding the effects of laser imprint on plastic-target implosions on OMEGA [J]. Phys Plasmas, 2016, 23(10): 102701. |
[4] |
Lindl J, Landen O, Edwards J, et al. Review of the national ignition campaign 2009-2012 [J]. Phys Plasmas, 2014, 21(2): 020501. |
[5] |
Eimerl D, Skupsky S, Myatt J, et al. A stardriver-class laser achieving 1 % beam uniformity in 1 ns [J]. Journal of Fusion Energy, 2016, 35(2): 459-469. |
[6] |
Dixit S, Feit M, Perry M, et al. Designing fully continuous phase screens for tailoring focal-plane irradiance profiles [J]. Opt Lett, 1996, 21: 1715-7. |
[7] |
Menapace J, Dixit S, Genin F, et al. Magnetorheological finishing for imprinting continuous phase plate structure onto optical surfaces[C]//SPIE, 2004, 5273: 220-230. |
[8] |
Kato Y, Mima K, Miyanaga N, et al. Random phasing of high-power lasers for uniform target acceleration and plasma-instability suppression [J]. Phys Rev Lett, 1984, 53(11): 1057-1060. |
[9] |
Gerchberg R W, Saxton W. A practical algorithm for the determination of phase from image and diffraction plane pictures [J]. Optik, 1971, 35: 237-250. |
[10] |
Dixit S N, Lawson J K, Manes K R, et al. Kinoform phase plates for focal plane irradiance profile control [J]. Opt Lett, 1994, 19(6): 417-419. |
[11] |
Lin Y, Kessler T, Lawrence G. Distributed phase plates for super-Gaussian focal-plane irradiance profiles [J]. Opt Lett, 1995, 20: 764-766. |
[12] |
Neauport J, Ribeyre X, Daurios J, et al. Design and optical characterization of a large continuous phase plate for Laser Integration Line and Laser Megajoule facilities [J]. Appl Opt, 2003, 42(13): 2377-2382. |
[13] |
Marozas J A. Fourier transform-based continuous phase-plate design technique: a high-pass phase-plate design as an application for OMEGA and the National Ignition Facility [J]. JOSA A, 2007, 24(1): 74. |
[14] |
Marozas J A, Collins T J B, Zuegel J D, et al. Continuous distributed phase-plate advances for high-energy laser systems [J]. Journal of Physics: Conference Series, 2016: 717. |
[15] |
Goodman J W. Statistical Optics[M]. Newyork: John Wiley & Sons, 2015. |
[16] |
Li Ping, Ma Chi, Li Jingqin, et al. Design of continuous phase plates for controlling spatial spectrum of focal spot [J]. High Power Laser and Particle Beams, 2008, 20(7): 1114. (in Chinese) |
[17] |
Lei Z M, Sun X Y, Lv F N, et al. Application of optical diffraction method in designing phase plates [J]. Chinese Physics B, 2016, 25(11): 114201. |
[18] |
Wen Shenglin, Hou Jing, Yang Chunlin, et al. Uniformity of near-field caused by continuous phase plates for beam smoothing [J]. High Power Laser and Particle Beams, 2011, 23(6): 1543. (in Chinese) |
[19] |
Deng X, Liang X, Chen Z, et al. Uniform illumination of large targets using a lens array [J]. Appl Opt, 1986, 25(3): 377-381. |
[20] |
Zheng Jianzhou, Yu Qingxu, Lu Yongjun, et al. Improved lens arrays optical system with controllable focuswidth for uniform irradiation [J]. Chinese Journal of Lasers, 2007, 34(3): 331-336. (in Chinese) |
[21] |
Craxton R S, Anderson K S, Boehly T R, et al. Direct-drive inertial confinement fusion: A review [J]. Phys Plasmas, 2015, 22(11): 110501. |
[22] |
Campbell M, Goncharov V, Sangster T, et al. Laser-direct-drive program: Promise, challenge, and path forward [J]. Matter Radiat Extrem, 2017, 2(2): 1-18. |
[23] |
Skupsky S, Short R W, Kessler T, et al. Improved laser‐beam uniformity using the angular dispersion of frequency‐modulated light [J]. J Appl Phys., 1989, 66(8): 3456-3462. |
[24] |
Yang Dong, Li Zhichao, Li Sanwei, et al. Laser plasma instability in indirect-drive inertial confinement fusion [J]. Scientia Sinica Physica, Mechanica & Astronomica, 2018, 48(6): 21-36. (in Chinese) |
[25] |
Willi O, Afshar-Rad T, Coe S, et al. Study of instabilities in long scale-length plasmas with and without laser-beam-smoothing techniques [J]. Physics of Fluids B: Plasma Physics, 1990, 2(6): 1318. |
[26] |
Regan S, Marozas J, Craxton S, et al. Performance of 1-THz-bandwidth, two-dimensional smoothing by spectral dispersion and polarization smoothing of high-power, solid-state laser beams [J]. J Opt Soc Am B-Opt Physics, 2005, 22(5): 998. |
[27] |
Lehmberg R H, Schmitt A J, Bodner S E. Theory of induced spatial incoherence [J]. J Appl Phys, 1987, 62(7): 2680-2701. |
[28] |
Regan S, Marozas J, Kelly J, et al. Experimental investigation of smoothing by spectral dispersion [J]. J Opt Soc Am B-Opt Physics, 2000, 17: 1483-1489. |
[29] |
Li F, Gao Y, Zhao X, et al. Induced spatial incoherence combined with continuous phase plate for the improved beam smoothing effect [J]. Opt Eng, 2018, 57(6): 066117. |
[30] |
Tsubakimoto K, Nakatsuka M, Nakano H, et al. Suppression of interference speckles produced by a random phase plate, using a polarization control plate [J]. Opt Commun, 1992, 91(1-2): 9-12. |
[31] |
Fuchs J, Labaune C, Depierreux S, et al. Modification of spatial and temporal gains of stimulated Brillouin and Raman scattering by polarization smoothing [J]. Phys Rev Lett, 2000, 84(14): 3089-3092. |
[32] |
Rothenberg J E. Polarization beam smoothing for inertial confinement fusion [J]. J Appl Phys, 2000, 87: 3654-3662. |
[33] |
Wang Y, Wang F, Zhang Y, et al. Polarization smoothing for single beam by a nematic liquid crystal scrambler [J]. Appl Opt, 2017, 56: 8087. |
[34] |
Spaeth M, Manes K, Kalantar D, et al. Description of the NIF Laser [J]. Fusion Science and Technology, 2016, 69: 25-145. |
[35] |
Zheng W, Wei X, Zhu Q, et al. Laser performance upgrade for precise ICF experiment in SG-Ⅲ Laser Facility [J]. Matter Radiat Extrem, 2017, 2(5): 243-255. |
[36] |
Skupsky S, Kessler T. Speckle‐free phase plate (diffuser) for far‐field applications [J]. J Appl Phys, 1993, 74: 4310-4316. |
[37] |
Dainty J. Laser Speckle and Related Phenomena[M]. New York: Springer-Verlag Berlin Heidelberg 1975. |
[38] |
Munro D, Dixit S, Langdon A, et al. Polarization smoothing in a convergent beam [J]. Appl Opt, 2005, 43: 6639-47. |
[39] |
Huang X, Jia H, Zhou W, et al. Experimental demonstration of polarization smoothing in a convergent beam [J]. Appl Opt, 2015, 54: 9786. |
[40] |
Ren Guangsen, Sun Quan, Wu Wuming, et al. Effect of radial polarization modulation on smoothing and polarization properties of focal speckle [J]. High Power Laser and Particle Beams, 2015, 27(12): 122008. (in Chinese) |
[41] |
Lehmberg R H, Obenschain S P. Use of induced spatial incoherence for uniform illumination of laser fusion targets [J]. Opt Commun, 1983, 46(1): 27-31. |
[42] |
Zhao X, Gao Y, Li F, et al. Beam smoothing by a diffraction-weakened lens array combining with induced spatial incoherence [J]. Appl Opt, 2019, 58(8): 2121-2126. |
[43] |
Obenschain S P, Pawley C J, Mostovych A N, et al. Reduction of Raman scattering in a plasma to convective levels using induced spatial incoherence [J]. Phys Rev Lett, 1989, 62(7): 768-771. |
[44] |
Li F, Gao Y, Zhao X, et al. Experiment and theory of beam smoothing using induced spatial incoherence with a lens array [J]. Appl Opt, 2020, 59(10): 2976-2982. |
[45] |
Veron D, Ayral H, Gouedard C, et al. Optical spatial smoothing of Nd-glass laser beam [J]. Opt Commun, 1988, 65(1): 42-46. |
[46] |
Donnat P, Gouédard C, Veron D, et al. Induced spatial incoherence and nonlinear effects in Nd: glass amplifiers [J]. Opt Lett, 1992, 17(5): 331-333. |
[47] |
Obenschain S P, Bodner S E, Colombant D, et al. The Nike KrF laser facility: Performance and initial target experiments [J]. Phys Plasmas, 1996, 3(5): 2098-2107. |
[48] |
Xiang Y, Star G, Tong X, et al. Beam-smoothing investigation on "Heaven I"-art. no. 62795Z[C]//SPIE, 2007, 6279: 62795Z. |
[49] |
Nakano H, Tsubakimoto K, Miyanaga N, et al. Spectrally dispersed amplified spontaneous emission for improving irradiation uniformity into high power Nd: glass laser system [J]. J Appl Phys, 1993, 73(5): 2122-2131. |
[50] |
Zhou Bingjie, Zhong Zheqiang, Zhang Bin. Influence of beam moving characteristics on smoothing effect of focal spot [J]. Acta Physica Sinica, 2012, 61(21): 214202. (in Chinese) |
[51] |
Zheng Tianran, Zhang Yong, Di Yongchao, et al. Theoretical research of “intensity sweep” laser beam smoothing characteristics [J]. Laser & Optoelectronics Progress, 2018, 55(11): 111405. (in Chinese) |
[52] |
Rothenberg J. Two-dimensional beam smoothing by spectral dispersion for direct-drive inertial confinement fusion[C]//SPIE, 1995, 2633. |
[53] |
Miyaji G, Miyanaga N, Urushihara S, et al. Three-directional spectral dispersion for smoothing of a laser irradiance profile [J]. Opt Lett, 2002, 27: 725-7. |
[54] |
Marozas J, Zuegel J, Collins T. Alternative laser-speckle-smoothing schemes for NIF direct-drive-ignition designs[C]//49th Annual Meeting of the Division of Plasma Physics, 2007. |
[55] |
Zhou Yuliang, Sun Zhzn, Liu Lanqin, et al. Research on beam smoothing technology for high-oower laser system [J]. Laser & Optoelectronics Progress, 2011(10): 41-48. (in Chinese) |
[56] |
Kelly J, Shvydky A, Marozas J, et al. Simulations of the propagation of multiple-FM smoothing by spectral dispersion on OMEGA EP[C]//SPIE, 2013, 8602: 86020D. |
[57] |
Holstein P A, André M, Casanova M, et al. Target design for the LMJ [J]. Applied Physics, 2000, 1: 693-704. |
[58] |
Duluc M, Penninckx D, Loiseau P, et al. Comparison of longitudinal and transverse smoothing by spectral dispersion on stimulated Brillouin backscattering in inertial confinement fusion plasmas [J]. Phys Plasmas, 2019, 26(4): 042707. |
[59] |
Zhang R, Zhang X, Sui Z, et al. Research on target uniform irradiation method using linearly modulated light and special grating dispersion [J]. Opt Laser Technol, 2011, 43(7): 1073-1077. |
[60] |
Eimerl D, Campbell E M, Krupke W F, et al. StarDriver: a flexible laser driver for inertial confinement fusion and high energy density physics [J]. Journal of Fusion Energy, 2014, 33(5): 476-488. |
[61] |
Eimerl D, Skupsky S, Campbell M. StarDriver: Recent results on beam smoothing and LPI mitigation [J]. Journal of Physics: Conference Series, 2016, 717: 012015. |
[62] |
Eimerl D. StarDriver: recent results on beam smoothing and 2ωpe mitigation [J]. Journal of Lasers, Optics & Photonics, 2016, 3(1): 1000130. |
[63] |
Zhong Zheqiang, Zhou Bingjie, Ye Rong, et al. A novel scheme of beam smoothing using multi-central frequency and multi-color smoothing by spectral dispersion [J]. Acta Physica Sinica, 2014, 63(3): 035201. (in Chinese) |
[64] |
Zhong Z, Hou P, Zhang B. Radial smoothing for improving laser-beam irradiance uniformity [J]. Opt Lett, 2015, 40: 5850. |
[65] |
Hou P, Zhong Z, Zhang B. Analysis and optimization of radial smoothing based on optical Kerr effect for irradiation improvement [J]. Opt Laser Technol, 2016, 85: 48-54. |
[66] |
Weng X, Li T, Zhong Z, et al. Analysis of illumination uniformity affected by small-scale self-focusing of a pump beam in the radial smoothing scheme [J]. Appl Opt, 2017, 56: 8902. |
[67] |
Zhong Z, Yi M, Sui Z, et al. Ultrafast smoothing scheme for improving illumination uniformities of laser quads [J]. Opt Lett, 2018, 43: 3285. |
[68] |
Tian Boyu, Zhong Zheqiang, Sui Zhan, et al. Ultrafast azimuthal beam smoothing scheme based on vortex beam [J]. Acta Physica Sinica, 2019, 68(2): 024207. (in Chinese) |
[69] |
Zhong Zheqiang, Zhang Bin. Conjugate rotation smoothing scheme for laser quad based on dual-frequency laser and spiral phase plate [J]. High Power Laser and Particle Beams, 2020, 32(1): 11012. (in Chinese) |
[70] |
Xiong Hao, Zhong Zheqiang, Zhang Bin, et al. Untrafast smoothing scheme based on dynamic interference structure between beamlets of laser quad [J]. Acta Physica Sinica, 2020, 69(6): 064206. (in Chinese) |
[71] |
Yi M, Zhong Z, Zhang B, et al. Combined implementation of smoothing technologies for improving illumination uniformity of laser quad in multi-directions [J]. Journal of Modern Optics, 2019, 66: 1-8. |
[72] |
Huang Yuan, Zhang Yinrui, Zhong Zheqiang, et al. Rapid Polarization rotation smoothing scheme based on interference of circularly polarized vortex beamlet [J]. Chinese Journal of Lasers, 2020, 47(9): 0905003. (in Chinese) |
[73] |
Afeyan B, Hüller S. Optimal control of laser plasma instabilities using Spike Trains of Uneven Duration and Delay (STUD pulses) for ICF and IFE[C]//EPJ Web of Conferences, 2012: 59. |
[74] |
Afeyan B, Hüller S. Optimal control of laser-plasma instabilities using Spike Trains of Uneven Duration and Delay: STUD pulses[C]//IEEE International Conference on Plasma Science, 2013, arXiv:1304.3960 |
[75] |
Hüller S, Afeyan B. Simulations of drastically reduced SBS with laser pulses composed of a Spike Train of Uneven Duration and Delay (STUD pulses)[C]//EPJ Web of Conferences, 2012: 59. |
[76] |
Albright B, Yin L, Afeyan B. Control of stimulated Raman scattering in the strongly nonlinear and kinetic regime using Spike Trains of Uneven Duration and Delay: STUD pulses [J]. Phys Rev Lett, 2013, 64(4): 043804. |
[77] |
Li Y, Wang S, Xu J, et al. Precise manipulation on spike train of uneven duration or delay pulses with a time grating system [J]. Opt Express, 2015, 23: 29484. |
[78] |
Kruschwitz B, Kelly J, Dorrer C, et al. Commissioning of a multiple-frequency modulation smoothing by spectral dispersion demonstration system on OMEGA EP[C]//SPIE, 2013, 8602: 86020E. |
[79] |
Hohenberger M, Shvydky A, Marozas J, et al. Optical smoothing of laser imprinting in planar-target experiments on OMEGA EP using multi-FM 1-D smoothing by spectral dispersion [J]. Physics of Plasmas, 2016, 23(9): 092702. |
[80] |
Zhou S, Lin Z, Jiang X. Beam smoothing by lens array with spectral dispersion [J]. Opt Commun, 2007, 272(1): 186-191. |
[81] |
JiangY, Wu R, Zhou S, et al. Performance of smoothing by spectral dispersion combined with distributed phase plate on SG-II[C]//SPIE, 2013, 8904: 890403. |
[82] |
Feng Wen, Li Qinghui, Zhou Shenlei, et al. Experimental study of two-dimensional smoothing by spectral dispersion with distributed phase plates [J]. Laser & Optoelectronics Progress, 2012, 49(5): 053001. (in Chinese) |
[83] |
Jiang Xiujuan, Zhou Shenlei, Lin Zunqi, et al. Improving of the irradiation uniformity on targets with a diffraction-weakened lens array and spectral dispersion smoothing [J]. Acta Physica Sinica, 2006, 55(11): 5824. |
[84] |
Beau V, Valla D, Daurios J, et al. Metrology of focusing gratings and continuous phase plates for LIL and LMJ lasers[C]//SPIE, 2004, 5252. |
[85] |
Pawley C, Gerber K, Lehmberg R, et al. Measurements of laser-imprinted perturbations and Rayleigh–Taylor growth with the Nike KrF laser [J]. Phys Plasmas, 1997, 4: 1969-1977. |
[86] |
Gao Y, Cui Y, Ji L, et al. Development of low-coherence high-power laser drivers for inertial confinement fusion [J]. Matter Radiat Extrem, 2020, 5(6): 065201. |
[87] |
Rao D, Gao Y, Cui Y, et al. 1 μJ nanosecond low-coherent laser source with precise temporal shaping and spectral control [J]. Opt Laser Technol, 2020, 122: 105850. |
[88] |
Cui Y, Gao Y, Rao D, et al. High-energy low-temporal-coherence instantaneous broadband pulse system [J]. Opt Lett, 2019, 44(11): 2859-2862. |
[89] |
Ji L, Zhao X, Liu D, et al. High-efficiency second-harmonic generation of low-temporal-coherent light pulse [J]. Opt Lett, 2019, 44(17): 4359-4362. |
[90] |
Zhao X, Ji L, Liu D, et al. Second-harmonic generation of temporally low-coherence light [J]. APL Photonics, 2020, 5(9): 091301. |
[91] |
Qiu Yue, Qian Liejia, Huang Hongyi, et al. Improve illumination uniformity by suppressing the diffraction of a lens array [J]. Chinese Journal of Lasers, 1995, 22(1): 27-31. (in Chinese) |