[1] Edwards M J, Patel P K, Lindl J D, et al. Progress towards ignition on the National Ignition Facility[J]. Physics of Plasmas, 2011, 51(3): 1103-1107.

[2] Miquel J, Lion C, Vivini P, et al. The LMJ program: overview and status of LMJ & PETAL projects[C]//CLEO: 2013 .

[3] Song Wei, Zhang Ya'nan, Shen Linyong. Target positioning in high power laser device[J]. Optics and Precision Engineering, 2015, 23(2): 520-527. (in Chinese)

[4] Yan Yadong, He Junhua, Wang Feng, et al. Design of optical system for SG-III near backscatter diagnosis[J]. Optics and Precision Engineering, 2014, 22(6): 1469-1476. (in Chinese)

[5] Orth C D, Payne S A, Krupke W F. A diode pumped solid state laser driver for inertial fusion energy[J]. Nuclear Fusion, 1996, 36(1): 75-116.

[6] Bayramian A, Armstrong P, Ault E, et al. The mercury project: a high average power, gas-cooled laser for inertial fusion energy development[J]. Fusion Science and Technology, 2007, 52(3): 383-387.

[7] Banerjee S, Ertel K, Mason P D, et al. High-efficiency 10 J diode pumped cryogenic gas cooled Yb:YAG multislab amplifier[J]. Opt Lett, 2012, 37(12): 2175-2177.

[8] Siebold M, Loeser M, Harzendorf G, et al. High-energy diode-pumped D2O-cooled multislab Yb:YAG and Yb:QX-glass lasers[J]. Opt Lett, 2014, 39(12): 3611-3614.

[9] Krupke W F. Ytterbium solid-state lasers-The first decade[J]. IEEE Journal of Selected Topics in Quantum Electronics, 2000, 6(6): 1287-1296.

[10] Chanteloup J C, Albach D, Lucianetti A, et al. Multi kJ level laser concepts for HiPER facility[C]//The 6th International Conference on Inertial Fusion Sciences and Applications, 2010, 222: 1742-1780.

[11] Bayramian A, Aceves S, Anklam T, et al. Compact, Efficient laser systems required for laser inertial fusion energy[J]. Fusion Science And Technology, 2011, 60(1): 28-48.

[12] Rus B, Bakule P, Kramer D, et al. ELI-Beamlines laser systems: status and design options[C]//Proc of SPIE, 2013, 8780: 87801T.

[13] Zhi Yin, Li Long, Shi Peng, et al. Temperature field of pulse LD end pumped Nd:YAG crystal[J]. Infrared and Laser Engineering, 2015, 44(2): 491-496. (in Chinese)

[14] Zhang Deping, Wu Chao, Zhang Rongzhu, et al. Study of thermal effect of LD end-pumped separated amplifier structure[J]. Infrared and Laser Engineering, 2015, 44(8): 2250-2255. (in Chinese)

[15] Bian Jintian, Wang Xi. Measuring thermal lens effect of LD-pumped solid-state laser[J]. Infrared and Laser Engineering, 2013, 42(S2): 391-394. (in Chinese)

[16] Slezak O, Lucianetti A, Divoky M, et al. Optimization of wavefront distortions and thermal-stress induced birefringence in a cryogenically-cooled multislab laser amplifier[J]. IEEE Journal of Quantum Electronics, 2013, 49(11): 960-966.

[17] Yan Xiongwei, Yu Haiwu, Cao Dingxiang, et al. ASE effect in pulsed energy-storage reprated Yb:YAG disk laser amplifier[J]. Acta Physica Sinica, 2009, 58(6): 4230-4238. (in Chinese)

[18] Rohsenow W M, Hartnett J P, Cho Y I. Handbook of Heat Transfer[M]. New York: McGraw-Hill, 1998.

[19] Timoshenko S, Goodier J N. Theory of Elasticity[M]. New York: McGraw-Hill , 1951.

[20] Born M, Wolf E. Principles of Optics[M]. Oxford: Pergamon, 1970.

[21] Ying C, Bin C, Patel M K R, et al. Calculation of thermal-gradient-induced stress birefringence in slab Lasers-I[J]. IEEE Journal of Quantum Electronics, 2004, 40(7): 909-916.

[22] Cousins A K. Temperature and thermal stress scaling in finite-length end-pumped laser rods[J]. IEEE Journal of Quantum Electronics, 1992, 28(4): 1057-1069.

[23] Aggarwal R L, Ripin D J, Ochoa J R, et al. Measurement of thermo-optic properties of Y3Al5O12, Lu3Al5O12, YAIO3, LiYF4, LiLuF4, BaY2F8, KGd(WO4)2, and KY(WO4)2 laser crystals in the 80-300 K temperature range[J]. Journal of Applied Physics, 2005, 98(10): 1035114.

[24] Brown D C. Ultrahigh-average-power diode-pumped Nd:YAG and Yb:YAG lasers[J]. IEEE Journal of Quantum Electronics, 1997, 33(5): 861-873..