[1] Bourdet G. Comparison of pulse amplification performances in longitudinally pumped ytterbium doped materials[J]. Opt Commun, 200, 331-342(2001).

[2] Yu Haiwu, Duan Wentao, Xu Meijian. Review of ytterbium-doped laser materials[J]. Laser &Optoelectronics Progress, 44, 30-41(2007).

[3] Bayramian A, Armstrong P, Ault E. The Mercury project: A high average power, gas-cooled laser for inertial fusion energy development[J]. Fus Sci Technol, 52, 383-387(2007).

[4] Dong Jun, Bass Michael, Mao Yanli. Dependence of the Yb³⁺ emission cross section and lifetime on temperature and concentration in yttrium aluminum garnet[J]. Journal of the Optical Society of America B, 20, 1975-1979(2003).

[5] Gonçalvès-Novo T, Albach D, Vincent B. 14 J/2 Hz Yb³⁺: YAG diode pumped solid state laser chain[J]. Optics Express, 21, 855-866(2013).

[6] Marrazzo S, Gonçalvès-Novo T, Millet F. Low temperature diode pumped active mirror Yb³⁺: YAG disk laser amplifier studies[J]. Optics Express, 24, 12651-12660(2016).

[7] Mason P, Divoký M, Butcher T, et al. Commissioning of a kWclass nanosecond pulsed DPSSL operating at 105 J, 10 Hz [C]Proceedings of the SPIE. 2017: 102380H.

[8] Iyama K, Tokita S, Kawashim T, et al. Development of subns, 1 J Yb: YAG TRAM multipass amplifier[C]HECDPSSL. 2017.

[9] Kabeya Y, Mita T, Hatano Y, et al. Development of a 10J, 10Hz laser amplifier system with cryocooled Yb: YAG ceramics using activemirr method [C]Proc of SPIE. 2019: 108960M.

[10] Han Chi, Baumgarten C M, Jankowska E. Thermal behavior characterization of a kilowatt-power-level cryogenically cooled Yb: YAG active mirror laser amplifier[J]. Journal of the Optical Society of America B, 36, 1084-1090(2019).

[11] Liu Tinghao, Sui Zhan, Chen Lin. 12 J, 10 Hz diode-pumped Nd: YAG distributed active mirror amplifier chain with ASE suppression[J]. Optics Express, 25, 21981-21992(2017).

[12] Zheng Jiangang, Jiang Xinying, Yan Xiongwei. Progress of the 10 J water-cooled Yb: YAG laser system in RCLF[J]. High Power Laser Science and Engineering, 2, e27(2014).

[13] Jiang Xinying, Yan Xiongwei, Wang Zhenguo. Influence of thermal reduced depolarization on a repetition-frequency laser amplifier and compensation[J]. High Power Laser Science and Engineering, 3, e9(2015).