Exploration of the multiparameter space of nanosecond-laser damage growth in fused silica optics

Applied Optics

Volumn 50, Issue 22, 2011, Pages D12-D20

  Negres, Raluca A ^a   Liao, Zhi M ^a   Abdulla, Ghaleb M ^a   Cross, David A ^a   Norton, Mary A ^a   Carr, Christopher W ^a  

^a LAWRENCE LIVERMORE NATIONAL LABORATORY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CLUSTERING ALGORITHMS; FUSED SILICA; WEIBULL DISTRIBUTION;

ANALYSIS APPROACH; FUSED SILICA OPTICS; MULTI-PARAMETER SPACE; NANOSECOND LASER PULSE; NANOSECOND LASERS; PREDICTIVE MODELS; WEIBULL COEFFICIENTS; WEIBULL STATISTICS;

LASER DAMAGE;

EID: 79959917760     PISSN: 1559128X     EISSN: 21553165     Source Type: Journal    
DOI: 10.1364/AO.50.000D12     Document Type: Article

References (47)

1. M. R. Kozlowski, R. P. Mouser, S. M. Maricle, P. J. Wegner, and T. L. Weiland, “Laser damage performance of fused silica optical components measured on the beamlet laser at 351 nm,” Proc. SPIE 3578, 436-445 (1999).
2. A. Conder, J. Chang, L. Kegelmeyer, M. Spaeth, and P. Whitman, “Final optics damage inspection (FODI) for the National Ignition Facility,” Proc. SPIE 7797, 77970P (2010).
3. H. Bercegol, A. Boscheron, J. M. Di-Nicola, E. Journot, L. Lamaignere, J. Neauport, and G. Raze, “Laser damage phenomena relevant to the design and operation of an ICF laser driver,” J. Phys. Conf. Ser. 112, 032013 (2008).
4. S. G. Demos and M. Staggs, “Application offluorescence microscopy for noninvasive detection of surface contamination and precursors to laser-induced damage,” Appl. Opt. 41, 1977-1983 (2002).
5. F. Bonneau, P. Combis, J. L. Rullier, M. Commandré, A. During, J. Y. Natoli, M. J. Pellin, M. R. Savina, E. Cottancin, and M. Pellarin, “Observation by photothermal microscopy of increased silica absorption in laser damage induced by gold nanoparticles,” Appl. Phys. Lett. 83, 3855-3857 (2003).
6. T. I. Suratwala, P. E. Miller, J. D. Bude, W. A. Steele, N. Shen, M. V. Monticelli, M. D. Feit, T. A. Laurence, M. A. Norton, C. W. Carr, and L. L. Wong, “HF-based etching processes for improving laser damage resistance offused silica optical surfaces,” J. Am. Ceram. Soc. 94, 416-428 (2011).
7. 2,” Proc. SPIE 6403, 64030K (2006).
8. C. W. Carr, J. B. Trenholme, and M. L. Spaeth, “Effect of temporal pulse shape on optical damage,” Appl. Phys. Lett. 90, 041110 (2007).
9. 2 surfaces,” Proc. SPIE 7132, 71321C (2008).
10. S. G. Demos, M. Staggs, and M. R. Kozlowski, “Investigation of processes leading to damage growth in optical materials for large-aperture lasers,” Appl. Opt. 41, 3628-3633 (2002).
11. S. O. Kucheyev and S. G. Demos, “Optical defects produced in fused silica during laser-induced breakdown,” Appl. Phys. Lett. 82, 3230-3232 (2003).
12. R. A. Negres, M. W. Burke, P. DeMange, S. B. Sutton, M. D. Feit, and S. G. Demos, “Thermal imaging investigation of modified fused silica at surface damage sites for understanding the underlying mechanisms of damage growth,” Proc. SPIE 6403, 640306 (2006).
13. R. A. Negres, M. W. Burke, S. B. Sutton, P. DeMange, M. D. Feit, and S. G. Demos, “Evaluation of UV absorption coefficient in laser-modified fused silica,” Appl. Phys. Lett. 90, 061115 (2007).
14. H. Bercegol, P. Grua, D. Hebert, and J. P. Morreeuw, “Progress in the understanding offracture related laser damage offused silica,” Proc. SPIE 6720, 672003 (2007).
15. 2 laser,” J. Appl. Phys. 97, 113-519 (2005).
16. J. Wong, J. L. Ferriera, E. F. Lindsey, D. L. Haupt, I. D. Hutcheon, and J. H. Kinney, “Morphologyand microstructure in fused silica induced by high fluence ultraviolet 3® (355 nm) laser pulses,” J. Non-Cryst. Solids 352, 255-272 (2006).
17. C. W. Carr, H. B. Radousky, A. M. Rubenchik, M. D. Feit, and S. G. Demos, “Localized dynamics during laser-induced damage in optical materials,” Phys. Rev. Lett. 92, 087401 (2004).
18. T. A. Laurence, J. D. Bude, N. Shen, T. Feldman, P. E. Miller, W. A. Steele, and T. Suratwala, “Metallic-like photoluminescence and absorption in fused silica surface flaws,” Appl. Phys. Lett. 94, 151114 (2009).
19. R. A. Negres, M. D. Feit, P. DeMange, J. D. Bude, and S. G. Demos, “Pump and probe damage testing for investigation of transient material modifications associated with laser damage in optical materials,” Proc. SPIE 6720, 672019 (2007).
20. R. A. Negres, M. D. Feit, and S. G. Demos, “Dynamics of material modifications following laser-breakdown in bulk fused silica,” Opt. Express 18, 10642-10649 (2010).
21. C. W. Carr, J. D. Bude, and P. DeMange, “Laser-supported solid-state absorption fronts in silica,” Phys. Rev. B 82, 184-304 (2010).
22. 2 laser heating of defect populations on fused silica surfaces using photoluminescence microscopy,” Opt. Express 18, 15207-15215 (2010).
23. R. A. Negres, M. A. Norton, D. A. Cross, and C. W. Carr, “Growth behavior of laser-induced damage on fused silica optics under UV, ns laser irradiation,” Opt. Express 18, 1996619976 (2010).
24. M. A. Norton, L. W. Hrubesh, Z. Wu, E. E. Donohue, M. D. Feit, M. R. Kozlowski, D. Milam, K. P. Neeb, W. A. Molander, A. M. Rubenchik, W. D. Sell, and P. Wegner, “Growth of laser initiated damage in fused silica at 351 nm,” Proc. SPIE 4347, 468 (2001).
25. G. Raze, J. M. Morchain, M. Loiseau, L. Lamaignere, M. Josse, and H. Bercegol, “Parametric study of the growth of damage sites on the rear surface of fused silica windows,” Proc. SPIE 4932, 127-135 (2003).
26. M. A. Norton, E. E. Donohue, W. G. Hollingsworth, J. N. McElroy, and R. P. Hackel, “Growth of laser initiated damage in fused silica at 527 nm,” Proc. SPIE 5273, 236-243 (2004).
27. M. A. Norton, E. E. Donohue, W. G. Hollingsworth, M. D. Feit, A. M. Rubenchik, and R. P. Hackel, “Growth of laser initiated damage in fused silica at 1053 nm,” Proc. SPIE 5647, 197205 (2005).
28. 2 under multiple wavelength irradiation,” Proc. SPIE 5991, 599108 (2005).
29. 2,” Proc. SPIE 6720, 67200F (2007).
30. M. A. Norton, A. V. Carr, C. W. Carr, E. E. Donohue, M. D. Feit, W. G. Hollingsworth, Z. Liao, R. A. Negres, A. M. Rubenchik, and P. Wegner, “Laser damage growth in fused silica with simultaneous 351 nm and 1053 nm irradiation,” Proc. SPIE 7132, 71321H (2008).
31. 2 at 351 nm,” Proc. SPIE 6403, 64030L (2006).
32. W. Q. Huang, W. Han, F. Wang, Y. Xiang, F. Q. Li, B. Feng, F. Jing, X. F. Wei, W. G. Zheng, and X. M. Zhang, “Laser induced damage growth on large aperture fused silica optical components at 351 nm,” Chin. Phys. Lett. 26, 017901 (2009).
33. M. A. Norton, J. J. Adams, C. W. Carr, E. E. Donohue, M. D. Feit, R. P. Hackel, W. G. Hollingsworth, J. A. Jarboe, M. J. Matthews, A. M. Rubenchik, and M. L. Spaeth, “Growth of laser damage in fused silica: diameter to depth ratio,” Proc. SPIE 6720, 67200H (2007).
34. H. Bercegol, L. Lamaignere, B. L. Garrec, M. Loiseau, and P. Volto, “Self-focusing and rear surface damage in a fused silica window at 1064 nm and 355 nm,” Proc. SPIE 4932, 276285 (2003).
35. A. Salleo, R. Chinsio, and F. Y. Genin, “Crack propagation in fused silica during UV and IR ns-laser illumination,” Proc. SPIE 3578, 456-471 (1999).
36. R. Courchinoux, G. Raze, C. Sudre, M. A. Josse, A. C. L. Boscheron, C. Lepage, E. Mazataud, E. Bordenave, L. Lamaignere, M. Loiseau, T. Donval, and H. Bercegol, “Laser-induced damage growth with small and large beams: comparison between laboratory experiments and large-scale laser data,” Proc. SPIE 5273, 99-106 (2004).
37. M. C. Nostrand, T. L. Weiland, R. L. Luthi, J. L. Vickers, W. D. Sell, J. A. Stanley, J. Honig, J. Auerbach, R. P. Hackel, and P. Wegner, “A large aperture, high energy laser system for optics and optical components testing,” Proc. SPIE 5273, 325333 (2004).
38. R. A. Negres, M. A. Norton, Z. M. Liao, D. A. Cross, J. D. Bude, and C. W. Carr, “The effect of pulse duration on the growth rate of laser-induced damage sites at 351 nm on fused silica surfaces,” Proc. SPIE 7504, 750412 (2009).
39. R. R. Prasad, J. R. Bruere, J. M. Halpin, P. Lucero, S. Mills, M. Bernacil, and R. P. Hackel, “Design of a production process to enhance optical performance of 3® optics,” Proc. SPIE 5273, 296-302 (2004).
40. R. R. Prasad, J. R. Bruere, J. Peterson, J. M. Halpin, M. Borden, and R. P. Hackel, “Enhanced performance of large 3® optics using UV and IR lasers,” Proc. SPIE 5273, 288-295 (2004).
41. B. Bertussi, P. Cormont, S. Palmier, P. Legros, and J. L. Rullier, “Initiation oflaser-induced damage sites in fused silica optical components,” Opt. Express 17, 11469-11479 (2009).
42. W. Weibull, Fatigue Testing and Analysis of Results (Pergamon, 1961).
43. J. D. Kalbfkisch and R. L. Prentice, The Statistical Analysis of Failure Time Data (Wiley-Interscience, 1980).
44. E. L. Kaplan and P. Meier, “Non-parametric estimation from incomplete observations,” J. Am. Stat. Assoc. 53, 457-481 (1958).
45. I. H. Witten and E. Frank, Data Mining: Practical Machine Learning Tools and Techniques, 2nd ed. (Morgan Kaufmann, 2005).
46. P. Berkhin, “Survey of clustering data mining techniques,” Tech. Rep. (Accrue Software, San Jose, California, 2002).
47. J. Heebner, P. Wegner, and C. Haynam, “Programmable beam spatial shaping for the National Ignition Facility,” SPIE Newsroom (21 July 2010), doi:10.1117/2.1201007.003139, http://spie.org/x41261.xml?ArticleID=x41261.