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Dive into the research topics where Thomas Gene Parham is active.

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Featured researches published by Thomas Gene Parham.


Proceedings of SPIE | 2004

NIF final optics system: frequency conversion and beam conditioning

Paul J. Wegner; Jerome M. Auerbach; Thomas A. Biesiada; Sham N. Dixit; Janice K. Lawson; Joseph A. Menapace; Thomas Gene Parham; David W. Swift; Pamela K. Whitman; Wade H. Williams

Installation and commissioning of the first of forty-eight Final Optics Assemblies on the National Ignition Facility was completed this past year. This activity culminated in the delivery of first light to a target. The final optics design is described and selected results from first-article commissioning and performance tests are presented.


Laser-Induced Damage in Optical Materials: 2001 | 2002

Combined advanced finishing and UV-laser conditioning for producing UV-damage-resistant fused-silica optics

Joseph A. Menapace; B. M. Penetrante; Donald Golini; Albert Slomba; Philip E. Miller; Thomas Gene Parham; Mike Nichols; John Peterson

Laser-induced damage initiation on fused silica optics can limit the lifetime of the components when used in high power UV laser environments. For example in inertial confinement fusion research applications, the optics can be exposed to temporal laser pulses of about 3 nsec with average fluences of 8 J/cm2 and peak fluences between 12 and 15 J/cm2. During the past year, we have focused on optimizing the damage performance at a wavelength of 355-nm (3(omega) ), 3-nsec pulse length, for optics in this category by examining a variety of finishing technologies with a challenge to improve the laser damage initiation density by at least two orders of magnitude. In this paper, we describe recent advances in improving the 3(omega) damage initiation performance of laboratory-scale zirconium oxide and cerium oxide conventionally finished fused silica optics via application of processes incorporating magnetorheological finishing (MRF), wet chemical etching, and UV laser conditioning. Details of the advanced finishing procedures are described and comparisons are made between the procedures based upon large area 3(omega) damage performance, polishing layer contamination, and optical subsurface damage.


Laser-Induced Damage in Optical Materials: 2001 | 2002

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

Alan K. Burnham; Lloyd A. Hackel; Paul J. Wegner; Thomas Gene Parham; Lawrence W. Hrubesh; B. M. Penetrante; Pamela K. Whitman; Stavros G. Demos; Joseph A. Menapace; Michael J. Runkel; M.J. Fluss; Michael D. Feit; Michael H. Key; Thomas A. Biesiada

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.


Laser-Induced Damage in Optical Materials: 1998 | 1999

Manufacture, optical performance, and laser damage characteristics of diffractive optics for the National Ignition Facility

Jerald A. Britten; S. Herman; Leslie J. Summers; Michael C. Rushford; Lun Auyang; Ian M. Barton; Bruce W. Shore; Sham N. Dixit; Thomas Gene Parham; Curly R. Hoaglan; Charles T. Thompson; Colin L. Battersby; J. M. Yoshiyama; Ron P. Mouser

We have fabricated demonstration diffractive optic plates at full scale for the NIF laser. These include an off-axis focusing beam sampling grating, a color separation grating, and a kinoform phase plate for spatial beam smoothing. Fabrication methods and optical performance of these DOPs are discussed. IT was discovered that the sol-gel antireflective coating normally applied to high-power transmissive optics partially planarizes the diffractive structures, particularly on the color separation grating used for color management at target, to the extent that optical performance and laser damage threshold are negatively impacted. The effect of sol-gel coatings on grating performance, the feasibility of placing all diffractive structures on a single surface, and future work in this area are discussed.


Optics Express | 2017

Particle damage sources for fused silica optics and their mitigation on high energy laser systems

J. D. Bude; Christopher W. Carr; P. E. Miller; Thomas Gene Parham; Pamela K. Whitman; Marcus V. Monticelli; Rajesh N. Raman; David A. Cross; Brian Welday; Frank Ravizza; Tayyab I. Suratwala; J. Davis; Matthew J. Fischer; Ruth A. Hawley; H. Lee; Manyalibo J. Matthews; Mary A. Norton; Mike C. Nostrand; D. VanBlarcom; S. Sommer

High energy laser systems are ultimately limited by laser-induced damage to their critical components. This is especially true of damage to critical fused silica optics, which grows rapidly upon exposure to additional laser pulses. Much progress has been made in eliminating damage precursors in as-processed fused silica optics (the advanced mitigation process, AMP3), and very high damage resistance has been demonstrated in laboratory studies. However, the full potential of these improvements has not yet been realized in actual laser systems. In this work, we explore the importance of additional damage sources-in particular, particle contamination-for fused silica optics fielded in a high-performance laser environment, the National Ignition Facility (NIF) laser system. We demonstrate that the most dangerous sources of particle contamination in a system-level environment are laser-driven particle sources. In the specific case of the NIF laser, we have identified the two important particle sources which account for nearly all the damage observed on AMP3 optics during full laser operation and present mitigations for these particle sources. Finally, with the elimination of these laser-driven particle sources, we demonstrate essentially damage free operation of AMP3 fused silica for ten large optics (a total of 12,000 cm2 of beam area) for shots from 8.6 J/cm2 to 9.5 J/cm2 of 351 nm light (3 ns Gaussian pulse shapes). Potentially many other pulsed high energy laser systems have similar particle sources, and given the insight provided by this study, their identification and elimination should be possible. The mitigations demonstrated here are currently being employed for all large UV silica optics on the National Ignition Facility.


Laser-Induced Damage in Optical Materials: 2004 | 2005

Correlation of Laser-Induced Damage to Phase Objects in Bulk Fused Silica

Michael C. Nostrand; Charles Cerjan; Michael A. Johnson; Tayyab I. Suratwala; Timothy L. Weiland; Walter D. Sell; James L. Vickers; Ronald L. Luthi; Joel R. Stanley; Thomas Gene Parham; Charles B. Thorsness

The Optical Sciences Laser (OSL) Upgrade facility, described in last years proceedings, is a kJ-class, large aperture (100cm2) laser system that can accommodate prototype optical components for large-scale inertial confinement fusion lasers. High-energy operation of such lasers is often limited by damage to the optical components. Recent experiments on the OSL Upgrade facility using fused silica components at 4 J/cm2 (351-nm, 3-ns) have created output surface and bulk damage sites that have been correlated to phase objects in the bulk of the material. Optical Path Difference (OPD) measurements of the phase defects indicate the probability of laser-induced damage is strongly dependent on OPD.


Laser-Induced Damage in Optical Materials 2017 | 2017

Damage sources for the NIF Grating Debris Shield (GDS) and methods for their mitigation

J. D. Bude; Philip E. Miller; Thomas Gene Parham; Pam Whitman; Marcus V. Monticelli; Rajesh N. Raman; David A. Cross; Brian Welday; Frank Ravizza; Tayyab I. Suratwala; James Davis; Matthew J. Fischer; Ruth A. Hawley; Henry Lee; Manyalibo J. Matthews; Mary A. Norton; Michael C. Nostrand; Diana Vanblarcom; Stanley C. Sommer; Christopher W. Carr

The primary sources of damage on the National Ignition Facility (NIF) Grating Debris Shield (GDS) are attributed to two independent types of laser-induced particulates. The first comes from the eruptions of bulk damage in a disposable debris shield downstream of the GDS. The second particle source comes from stray light focusing on absorbing glass armor at higher than expected fluences. We show that the composition of the particles is secondary to the energetics of their delivery, such that particles from either source are essentially benign if they arrive at the GDS with low temperatures and velocities.


Storage and Retrieval for Image and Video Databases | 2001

Combined Advanced Finishing and UV-Laser Conditioning for Producing UV-Damage-Resistant Fused Silica Optics

Joseph A. Menapace; B. M. Penetrante; Donald Golini; Albert Slomba; Phillip E. Miller; Thomas Gene Parham; Matthew J. Nichols; John C. Peterson


Archive | 1994

Gegenstand mit lichtstreuender Beschichtung, Herstellung und Gebrauch

Pamela K. Whitman; Thomas Gene Parham


Archive | 1995

Lampe mit einem Schutzüberzug aus Siliziumoxyd Lamp with a protective coating of silicon oxide

Thomas Gene Parham; Leonard Edward Hoegler; Pamela K. Whitman

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Pamela K. Whitman

Lawrence Livermore National Laboratory

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Joseph A. Menapace

Lawrence Livermore National Laboratory

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B. M. Penetrante

Lawrence Livermore National Laboratory

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Tayyab I. Suratwala

Lawrence Livermore National Laboratory

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Brian Welday

Lawrence Livermore National Laboratory

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Christopher W. Carr

Lawrence Livermore National Laboratory

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David A. Cross

Lawrence Livermore National Laboratory

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Frank Ravizza

Lawrence Livermore National Laboratory

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