Mitigation of Ultraviolet Laser Damage on Fused Silica Surface with Femtosecond Laser System

Fang Zhou; Zhao Yuan′an; Chen Shunli; Hu Guohang; Liu Wenwen; Chen Weixiao; Li Dawei; Shao Jianda

doi:10.3788/cjl201340.0403001

[1] M. A. Norton, L. W. Hrubesh, Z. Wu et al.. Growth of laser initiated damage in fused silica at 351 nm［C］. SPIE, 2001, 4347: 468

[2] L. W. Hrubesh, M. A. Norton, W. A. Molander et al.. Methods for mitigation surface damage growth on NIF final optics［C］. SPIE, 2002, 4679: 23～33

[3] Hu Guohang, Zhao Yuan′an, Li Dawei. Technology and mechanism of CO2 laser treatment for mitigation surface damage growth［J］. Acta Optica Sinica, 2011, 31(8): 0814001

[4] I. L. Bass, G. M. Guss, R. P. Hackel. Mitigation of laser damage growth in fused silica with a galvanometer scanned CO2 laser［C］. SPIE, 2005, 5991: 59910C1

[5] I. L. Bass, G. M. Guss, M. J. Nostrand et al.. An improved method of mitigating laser induced surface damage growth in fused silica using a rastered, pulsed CO2 laser［C］. SPIE, 2010, 7842: 784220

[6] M. J. Matthews, I. L. Bass, G. M. Guss et al.. Downstream intensificaiton effects associated with CO2 laser mitigation of fused silica［C］. SPIE, 2007, 6720: 67200A

[7] L. Gallais, P. Cormont, J. L. Rullier. Investigation of stress induced by CO2 laser processing of fused silica optics for laser damage growth mitigation［J］. Opt. Express, 2009, 17: 23488～23501

[8] Li Xibin, Wang Haijun, Yuan Xiaodong et al.. Effects of CO2 laser irradiation on surface morphology and stress distribution of fused silica［J］. Chinese J. Laser, 2011, 38(9): 0903002

[9] M. D. Shirk, P. A. Molian. A review of ultrashort pulsed laser ablation of materials［J］. J. Laser. Appl., 1998, 10(1): 18～28

[10] X. Liu, D. Du, G. Mourous. Laser ablation and micromachining with ultrashort laser pulses［J］. IEEE. J. Quantum Electron., 1997, 33(10): 1706～1716

[11] M. Ali, T. Wagner, M. Shakoor. Review of laser nanomachining［J］. J. Laser. Appl., 2008, 20(3): 169～184

[12] Wang Yuerong, Li Yi, Wang Sijia. Directly writting single polarization microstructure waveguide in fused silica by high repetition rate femtosecond laser［J］. Chinese J. Laser, 2012, 39(12): 1203002

[13] J. E. Wolfe, S. R. Qiu, C. Stolz. Laser damage resistant pits in dielectric coatings created by femtosecond laser machining［C］. SPIE, 2009, 7504: 750405

[14] J. E. Wolfe, S. R. Qiu, C. J. Stolz. Fabrication of mitigation pits for improving laser damage resistance in dielectric mirrors by femtosecond laser machining［J］. Appl. Opt., 2011, 50(9): C457～C462

[15] D. Puerto, J. Siegel, W. Gawelda. Dynamics of plasma formation, relaxation, and topography modification induced by femtosecond laser pulses in crystalline and amorphous dielectrics［J］. J. Opt. Soc. Am. B, 2010, 27(5): 1065～1076

[16] M. A. Stevens-Kalceff, A. Stesmans, J. Wong. Defects induced in fused silica by high fluence ultraviolet laser pulses at 355 nm［J］. Appl. Phys. Lett., 2002, 80(5): 758～760

[17] H. Hosono, H. Kawazoe, N. Matsunami. Experimental evidence for Frenkel defect formation in amorphous SiO2 by electronic excitation［J］. Phys. Rev. Lett., 1998, 80(2): 317～320

[18] R. Tohmon, Y. Yamasaka, K. Nagasawa. Cause of the 5.0 eV absorption band in pure silica glass［J］. J. Non-Cryst. Solids, 1987, 95～96(part 2): 671～678

[19] H. Nishikawa, R. Nakamura, Y. Ohki. Enhanced photogeneration of E′ center form neutral oxygen vacancies in the pressure of hydrogen in high purity silica glass［J］. Phys. Rev. B, 1993, 48(5) : 2968～2973

[20] H. R. Philipp. Optical properties of non-crystalline Si, SiO, SiOx and SiO2［J］. J. Phys. Chem. Solids,1971, 32(8): 1935

[21] M. D. Feit, A. M. Rubenchik. Mechanisms of CO2 laser mitigation of laser damage growth in fused silica［C］. SPIE, 2003, 4932: 91～102

[22] Sun Chengwei. Laser Padiation Effect［M］. Beijing: National Defence Industry Press, 2002. 35

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