Improving 351-nm damage performance of large-aperture fused silica and DKDP optics

A program to identify and eliminate the causes of UV laser- induced damage and growth in fused silica and DKDP has developed methods to extend optics lifetimes for large- aperture, high-peak-power, UV lasers such as the National Ignition Facility (NIF). Issues included polish-related surface damage initiation and growth on fused silica and DKDP, bulk inclusions in fused silica, pinpoint bulk damage in DKDP, and UV-induced surface degradation in fused silica and DKDP in a vacuum. Approaches included an understanding of the mechanism of the damage, incremental improvements to existing fabrication technology, and feasibility studies of non-traditional fabrication technologies. Status and success of these various approaches are reviewed. Improvements were made in reducing surface damage initiation and eliminating growth for fused silica by improved polishing and post- processing steps, and improved analytical techniques are providing insights into mechanisms of DKDP damage. The NIF final optics hardware has been designed to enable easy retrieval, surface-damage mitigation, and recycling of optics.

[1]  Michael D. Feit,et al.  Analysis of bulk DKDP damage distribution, obscuration, and pulse-length dependence , 2001, SPIE Laser Damage.

[2]  J. Menapace,et al.  Combined advanced finishing and UV-laser conditioning for producing UV-damage-resistant fused silica optics , 2002 .

[3]  Michael D. Feit,et al.  Methods for mitigating surface damage growth in NIF final optics , 2002, SPIE Laser Damage.

[4]  Michael C. Staggs,et al.  Damage Measurements on Optical Materials for Use in High-Peak-Power Lasers , 1990 .

[5]  Stavros G. Demos,et al.  Mechanisms to explain damage growth in optical materials , 2000, SPIE Laser Damage.

[6]  M. Feit,et al.  Densification of fused silica due to shock waves and its implications for 351 nm laser induced damage. , 2001, Optics express.

[7]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[8]  Michael D. Feit,et al.  Extrapolation of damage test data to predict performance of large-area NIF optics at 355 nm , 1999, Laser Damage.

[9]  S. G. Demos,et al.  Luminescence Investigation of SiO * Surfaces Damaged by 0 . 35 mm Laser Illumination , 2000 .

[10]  Mark R. Kozlowski,et al.  Depth profiling of polishing-induced contamination on fused silica surfaces , 1998, Laser Damage.

[11]  Jürgen M. Plitzko,et al.  Initiation identification in fused-silica 35-nm optics , 2002, SPIE Laser Damage.

[12]  Lawrence W. Hrubesh,et al.  Localized CO2-laser treatment for mitigation of 351-nm damage growth in fused silica , 2002, SPIE Laser Damage.

[13]  Stavros G. Demos,et al.  Investigation of fluorescence microscopy as a tool for noninvasive detection and imaging of damage precursors at 351 nm , 2002, SPIE Laser Damage.

[14]  Michael J. Runkel,et al.  Laser raster conditioning of KDP and DKDP crystals using XeCl and Nd:YAG lasers , 2001, SPIE Laser Damage.

[15]  Stavros G. Demos,et al.  Spectroscopic investigation of SiO2 surfaces of optical materials for high-power lasers , 2000, LASE.

[16]  Albert F. Slomba,et al.  Combined advanced finishing and UV-laser conditioning for producing UV-damage-resistant fused-silica optics , 2002, SPIE Laser Damage.

[17]  I C Smith,et al.  Performance of a prototype for a large-aperture multipass Nd:glass laser for inertial confinement fusion. , 1997, Applied optics.

[18]  P. Wegner,et al.  A mathematical model for describing the intensity statistics of ICF laser beams , 1990 .

[19]  David Milam,et al.  Laser conditioning study of KDP on the optical sciences laser using large area beams , 1998, Laser Damage.

[20]  Mark R. Kozlowski,et al.  Application of total internal reflection microscopy for laser damage studies on fused silica , 1998, Laser Damage.

[21]  Alan K. Burnham,et al.  Differences in bulk damage probability distributions between tripler and z-cuts of KDP and DKDP at 355 nm , 2001, SPIE Laser Damage.

[22]  Joseph A. Menapace,et al.  UV-laser conditioning for reduction of 351-nm damage initiation in fused silica , 2002, SPIE Laser Damage.

[23]  F. Génin,et al.  Role of light intensification by cracks in optical breakdown on surfaces. , 2001, Journal of the Optical Society of America. A, Optics, image science, and vision.

[24]  J. Goodman Statistical Properties of Laser Speckle Patterns , 1963 .

[25]  Michael D. Feit,et al.  Growth of laser-initiated damage in fused silica at 351 nm , 2001, SPIE Laser Damage.

[26]  Michael J. Runkel,et al.  Surface defect generation in optical materials under high fluence laser irradiation in vacuum , 2000 .

[27]  Mark R. Kozlowski,et al.  Effects of wet etch processing on laser-induced damage of fused silica surfaces , 1999, Laser Damage.

[28]  Michael J. Runkel,et al.  Engineered defects for investigation of laser-induced damage of fused silica at 355 nm , 2002, SPIE Laser Damage.

[29]  Stavros G. Demos,et al.  Chemical etch effects on laser-induced surface damage growth in fused silica , 2001, SPIE Laser Damage.

[30]  John E. Peterson,et al.  CO2-laser polishing for reductoin of 351-nm surface damage initiation in fused silica , 2002, SPIE Laser Damage.

[31]  Michael J. Runkel,et al.  Effect of vacuum on the occurrence of UV-induced surface photoluminescence, transmission loss, and catastrophic surface damage , 2000, SPIE Optics + Photonics.

[32]  Semyon Papernov,et al.  Using colloidal gold nanoparticles for studies of laser interaction with defects in thin films , 2001, SPIE Laser Damage.

[33]  Michael D. Feit,et al.  Structural modifications in fused silica due to laser-damage-induced shock compression , 2002, SPIE Laser Damage.

[34]  Alan K. Burnham,et al.  Results of pulse-scaling experiments on rapid-growth DKDP triplers using the Optical Sciences Laser at 351 nm , 2001, SPIE Laser Damage.

[35]  N. C. Kerr The effect of laser annealing on laser induced damage threshold , 1990, Laser Damage.

[36]  Mark R. Kozlowski,et al.  Laser damage performance of fused silica optical components measured on the beamlet laser at 351 nm , 1999, Laser Damage.

[37]  Natalia P. Zaitseva,et al.  Design and benefits of continuous filtration in rapid growth of large KDP and DKDP crystals , 1999 .