Precise laser pulse shaping technology and application with high energy stability

Zhaoyu Zong; Junpu Zhao; Sen Li; Yue Liang; Ke Yao; Xiaocheng Tian; Xiaoxia Huang; Bo Chen; Wanguo Zheng

doi:10.11884/HPLPB202234.210288

[1] Zhang F, Cai H B, Zhou W M, et al. Enhanced energy coupling for indirect-drive fast-ignition fusion targets[J]. Nature Physics, 16, 810-814(2020).

[2] Gopalaswamy V, Betti R, Knauer J P, et al. Tripled yield in direct-drive laser fusion through statistical modelling[J]. Nature, 565, 581-586(2019).

[3] Jing Longfei, Jiang Shaoen, Kuang Longyu, et al. Comparison of three hohlraum configurations with six laser entrance holes for indirect-drive inertial confinement fusion[J]. Nuclear Fusion, 58, 096017(2018).

[4] Betti R, Hurricane O A. Inertial-confinement fusion with lasers[J]. Nature Physics, 12, 435-448(2016).

[6] Zheng Wanguo, Wei Xiaofeng, Zhu Qihua, et al. Laser performance upgrade for precise ICF experiment in SG-Ⅲ laser facility[J]. Matter and Radiation at Extremes, 2, 243-255(2017).

[7] Spaeth M L, Manes K R, Kalantar D H, et al. Description of the NIF Laser[J]. Fusion Science and Technology, 69, 25-145(2016).

[9] Fan Wei, Jiang Youen, Wang Jiangfeng, et al. Progress of the injection laser system of SG-II[J]. High Power Laser Science and Engineering, 6, e34(2018).

[10] Li Ping, Wang Wei, Jin Sai, et al. The shaped pulses control and operation on the SG-III prototype facility[J]. Laser Physics, 28, 045004(2018).

[12] Guardalben M J, Barczys M, Kruschwitz B E, et al. Laser-system model for enhanced operational performance and flexibility on OMEGA EP[J]. High Power Laser Science and Engineering, 8, e8(2020).

[13] Shaw M, House R. Laser perfmance operations model (LPOM): the computational system that automates the setup perfmance analysis of the National Ignition Facility[C]Proceedings of SPIE 9345 High Power Lasers f Fusion Research III. 2015: 93450E.

[14] Brunton G, Erbert G, Browning D, et al. The shaping of a national ignition campaign pulsed waveform[J]. Fusion Engineering and Design, 87, 1940-1944(2012).

[15] Zhao Junpu, Liang Yue, Li Sen, et al. Beam nonunifmity compensating by the programmable spatial shaper f the integration test bed[C]Proceedings of the SPIE 11052 Third International Conference on Photonics Optical Engineering. 2019: 110521R.

[16] Zhao Junpu, Wang Wenyi, Fu Xuejun, et al. Recent progress of the Integration Test Bed[C]Proceedings of the SPIE 9266 HighPower Lasers Applications VII. 2014: 92660X.

[17] Yao Ke, Gao Song, Tang Jun, et al. Off-axis eight-pass neodymium glass laser amplifier with high efficiency and excellent energy stability[J]. Applied Optics, 57, 8727-8732(2018).

[18] Yao Ke, Xie Xudong, Tang Jun, et al. Diode-side-pumped joule-level square-rod Nd: glass amplifier with 1 Hz repetition rate and ultrahigh gain[J]. Optics Express, 27, 32912-32923(2019).

[19] Zhang Rui, Tian Xiaocheng, Zhou Dandan, et al. Single-mode millijoule fiber laser system with high pulse shaping ability[J]. Optik, 157, 1087-1093(2018).

[20] Xu Dangpeng, Tian Xiaocheng, Zhou Dandan, et al. Temporal pulse precisely sculpted millijoule-level fiber laser injection system for high-power laser driver[J]. Applied Optics, 56, 2661-2666(2017).

CLP Journals