[1] [1] Jiang Zhonghong. ICF laser glass[J]. Chinese J Lasers, 2006, 33(9): 1265-1276.

[2] [2] Lin Zunqi. Progress of laser fusion[J]. Chinese J Lasers, 2010, 37(9): 2202-2207.

[3] [3] Hu Lili, Chen Shubin, Meng Tao, et al.. Advances in high performance large neodymium laser glasses[J]. High Power Laser and Particle Beams, 2011, 23(10): 2560-2565.

[4] [4] L L Hu, S B Chen, J P Tang, et al.. Large aperture N31 neodymium phosphate laser glass for use in a high power laser facility[J]. High Power Laser Science and Engineering, 2014, 2(1): 1-6.

[5] [5] C Goren, Y Tzuk, G Marcuset, et al.. Amplified spontaneous emission in slab amplifiers[J]. IEEE J Quan Electron, 2006, 42(12): 1239-1247.

[6] [6] P Peterson, A Gavrielides, T C Newell, et al.. ASE in thin disk lasers: Theory and experiment[J]. Opt Express, 2011, 19(25): 25672-25684.

[7] [7] J M Mcmahon, J L Emmett, J F Holzrichter, et al.. A glass-disk-laser amplifier[J]. IEEE J Quan Electron, 1973, 9(10): 992-999.

[8] [8] D C Brown, S D Jacobs, N Nee. Parasitic oscillations, absorption, stored energy density and heat density in active mirror and disk amplifiers[J]. Appl Opt, 1978, 17(2): 211-224.

[9] [9] K Contag, M Karszewski, C Stewen, et al.. Theoretical modeling and experimental investigations of the diode-pumped thin disk Yb:YAG laser[J]. IEEE J Quan Electron, 1999, 29(8): 697-703.

[10] [10] D Albach, J C Chanteloup, G L Touz. Influence of ASE on the gain distribution in large size, high gain Yb3 + :YAG slabs[J]. Opt Express, 2009, 17(5): 3792-3801.

[11] [11] J Speiser. Scaling of thin disk lasers influence of amplified spontaneous emission[J]. J Opt Soc Am, 2009, 26(1): 26-35.

[12] [12] M Sawicka, M Divoky, A Lucianetti, et al.. Effect of amplified spontaneous emission and parasitic oscillations on the performance of cryogenically-cooled slab amplifiers[J]. Laser and Particle Beams, 2013, 31: 553-560.

[13] [13] J A Glaze, S Guch. J B Trenholme. Parasitic suppression in large aperture Nd:glass disk laser amplifiers[J]. Appl Opt, 1974, 13(12): 2808-2811.

[14] [14] J R Guch. Parasitic suppression in large aperture disk lasers employing liquid edge claddings[J]. Appl Opt, 1976, 15(6): 1453-1457.

[15] [15] F G Patterson, J Bonlie, D Price, et al.. Suppression of parasitic lasing in large-aperture Ti:sapphire laser amplifiers[J]. Opt Lett, 1999, 24(14): 963-965.

[16] [16] A K Sridharan, S Saraf, S Sinha, et al.. Zigzag slabs for solid- state laser amplifiers: Batch fabrication and parasitic oscillation suppression[J]. Appl Opt, 2006, 4(14): 3340-3351.

[17] [17] X Y Liang, Y X Leng, C Wang, et al.. Parasitic lasing suppression in high gain femtosecond peta watt Ti:sapphire amplifier[J]. Opt Express, 2007, 15(23): 15335-15341.

[18] [18] K Ertel, C Hooker, S J Hawkes, et al.. ASE suppression in a high energy Titanium sapphire amplifier[J]. Opt Express, 2008, 16(11): 8039-8049.

[19] [19] Y L Zhang, X F Wei, M Z Li, et al.. Parasitic oscillation suppression in high-gain solid-state amplifiers[J]. Laser Phys, 2013, 23(5): 055802.

[20] [20] E C Honea, R J Beach. Parasitic Oscillation Suppression in Solid State Lasers Using Optical Coatings: US, 20020118718A1[P]. 2002-08-29.

[21] [21] Murray. Silicon Edge Claddings[R]. Laser Program Annual Report, UCRL-50021-83, 1984.

[22] [22] H Powell, M Riley, C R Wolfe. Composite Polymer Glass Edge for Laser Disks: US, 4849036[P]. 1989-07-18.

[23] [23] T Meng, J Tang, J Hu, et al.. Edge Cladding Technology to Suppress the Amplified Stimulated Emission (ASE) of the Laser Disks: China, ZL201010273819.7[P]. 2013-10-27.

[24] [24] Liu Jiu. Mechanical Behavior on Bonding Structure of Optical Mechanical System[D]. Changchun: Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sclences, 2011.

[25] [25] Liao Jiasheng, Gong Yan, Yuan Wenquan, et al.. Analysis of curing stress magnitude about low stress optical structure adhesives under stable temperature[J]. Opto-Electronic Engineering, 2013, 40(5): 138-143.

[26] [26] Liu Qiang, He Xin. Investigation on solidification techniques of pastern in space mirror[J]. Machinery Design and Manufacture, 2011, (2): 118-120.

[27] [27] Yuan Jinying, Pan Caiyuan. The essence and removing methods of internal stress due to volume shrinkage during Kesin curing period[J]. Chemistry and Adhesion, 1998, (4): 234-240.

[28] [28] Zhou Guangquan, Liu Xiaoming. Viscoelastic Theory[M]. Hefei: University of Chinese Science and Technology Press, 1996.

[29] [29] Li Jianfeng, Yang Fei, Ming Ming, et al.. Research on the thermal stress of bond connection used in telescope primary mirror support system[J]. Journal of Changchun University of Science and Technology (Natural Science Edition), 2012, 35(1): 13-17.

[30] [30] Gong Dajun, Wei Borong, Liu Yuyang, et al.. Influence of materials linear expansion coefficient on tensile shear performance[J]. China Adhesives, 2008, 17(10): 37-40.

[31] [31] H W Mckenzie, R J Hand. Basic Optical Stress Measurement in Glass[M]. Sheffield UK: Society of Glass Technology Press, 2011.

[32] [32] H Katte. Imaging measurement of stress birefringence in optical materials and components[J]. Photonik International (s1432-9778), 2009, 1: 39-41.

[33] [33] Е Э D Krzyzewski. Principles of Optical Glass Linear Annealing[M]. Beijing: National Defense Industry Press, 1965.