[5] Ma Zhe, Li Daijun, Gao Jiancun, et al. Thermal effects of the diode end-pumped Nd: YVO4 slab[J]. Optics Communications, 275, 179-185(2007).
[7] Chen Xiaoming, Lu Yanhua, Hu Hao, et al. Narrow-linewidth, quasi-continuous-wave ASE source based on a multiple-pass Nd: YAG zigzag slab amplifier configuration[J]. Optics Express, 26, 5602-5608(2018).
[8] Kane T J, Eggleston J M, Byer R L. The slab geometry laser—Part II: thermal effects in a finite slab[J]. IEEE Journal of Quantum Electronics, 21, 1195-1210(1985).
[9] Guo Chuan, Zuo Junwei, Bian Qi, et al. Compact, high-power, high-beam-quality quasi-CW microsecond five-pass zigzag slab 1319 nm amplifier[J]. Applied Optics, 56, 3445-3448(2017).
[10] Shin J S, Cha Y H, Lim G, et al. Wavefront improvement in an end-pumped high-power Nd: YAG zigzag slab laser[J]. Optics Express, 25, 19309-19319(2017).
[12] Chen Ying, Liu Ke, Yang Jing, et al. 8.2 mJ, 324 MW, 5 kHz picosecond MOPA system based on Nd: YAG slab amplifiers[J]. Journal of Optics, 18, 075503(2016).
[13] Chen Wei, Liu Bowen, Song Youjian, et al. High pulse energy fiber/solid-slab hybrid picosecond pulse system for material processing on polycrystalline diamonds[J]. High Power Laser Science and Engineering, 6, E18(2018).
[14] Kuznetsov I, Mukhin I, Palashov O, et al. Thin-rod Yb: YAG amplifiers for high average and peak power lasers[J]. Optics Letters, 43, 3941-3944(2018).
[16] Javed F, Zhang Hengli, Li Xiaowen, et al. 165 W, 1 MHz diodepumped Nd: YAG Innoslab picosecond amplifier[C]Proceedings of SPIE 11849 Fourth International Symposium on High Power Laser Science Engineering (HPLSE 2021). 2021: 118490T.
