NIF final optics system: frequency conversion and beam conditioning

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

doi:10.1117/12.538481

Cited by 80 publications

(31 citation statements)

References 10 publications

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“…We were able to provide experimental data demonstrating that high-performance optics can be made and imprinted using MRF using small optics fabricated at LLNL and large-aperture optics made using optimized manufacturing processes. In particular, we have shown that a CPP manufactured using advanced finishing protocols and performed beyond expectation during damage testing by sustaining only two damage sites, one at 12 J/cm 2 and one at 14 J/cm 2 . This result provides a basis for using MRF imprinting as a method of making CPPs that can be placed in either the infrared (1053 nm) and the ultraviolet (351 nm) portions of high-powered laser systems operating at or around 3-nsec pulse width.…”

Section: Discussionmentioning

confidence: 99%

“…Our development of CPP imprinting technology has, for the most part, focused upon applications where the CPPs are used in the infrared (1053 nm) portion of high-power laser systems and designed for far-field characteristics in the ultraviolet (351 nm) 2,11 . The CPP designs are, however, achromatic and can be used at any wavelength with nearly constant results.…”

Section: Large-aperture Continuous Phase Plates Manufacturementioning

confidence: 99%

“…Different experimental conditions at the target plane in an ICF laser system require that several different plate designs be manufactured. These conditions include indirect and direct drive implosion cone beams and backlighter/backscatter diagnostic beam drivers [1][2][3] . As such, CPPs are considered user prescribed optics and are tailored for each particular experiment.…”

Section: Functionality Of Cpps In High-power Lasersmentioning

confidence: 99%

“…Our group has been successful in the past two years at developing advanced Magnetorheological Finishing (MRF) technology to accurately apply complex topographical patterns onto optical surfaces that can be used to manipulate and control laser beam-shapes, energy distributions, and wavefront profiles. The most interesting and direct application of this advanced technology is its use in the manufacture of large-aperture (430 X 430 mm) custom continuous phase plates (CPPs) to improve on-target irradiation uniformity which, in turn, reduces hydrodynamic instabilities that develop during ICF implosions [1][2][3] .…”

Section: Introductionmentioning

confidence: 99%

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MRF applications: on the road to making large-aperture ultraviolet laser resistant continuous phase plates for high-power lasers

et al. 2006

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Over the past two years we have developed MRF tools and procedures to manufacture large-aperture (430 X 430 mm) continuous phase plates (CPPs) that are capable of operating in the infrared portion (1053 nm) of high-power laser systems. This is accomplished by polishing prescribed patterns of continuously varying topographical features onto finished plano optics using MRF imprinting techniques. We have been successful in making, testing, and using large-aperture CPPs whose topography possesses spatial periods as low as 4 mm and surface peak-to-valleys as high as 8.6 µm. Combining this application of MRF technology with advanced MRF finishing techniques that focus on ultraviolet laser damage resistance makes it potentially feasible to manufacture large-aperture CPPs that can operate in the ultraviolet (351 nm) without sustaining laser-induced damage. In this paper, we will discuss the CPP manufacturing process and the results of 351-nm/3-nsec equivalent laser performance experiments conducted on large-aperture CPPs manufactured using advanced MRF protocols.

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Section: Discussionmentioning

confidence: 99%

Section: Large-aperture Continuous Phase Plates Manufacturementioning

confidence: 99%

Section: Functionality Of Cpps In High-power Lasersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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MRF applications: on the road to making large-aperture ultraviolet laser resistant continuous phase plates for high-power lasers

et al. 2006

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“…A major portion of this work centers upon developing and engaging state-of-the-art technology to set the stage for creating nuclear fusion in a laboratory setting. Continuous phase plates (CPPs) form the vital and enabling portion of the optics chain used in these kilojoule-and megajoule-class laser systems because they make it possible to manipulate and control laser beam-shapes, energy distributions, and wavefront profiles 1,2,3,4,5,6,7 . This prescribed beam characteristic control is made possible via manipulation of the incoming wavefront by the CPPs.…”

Section: Large-aperture Cpp Imprintingmentioning

confidence: 99%

Developing magnetorheological finishing (MRF) technology for the manufacture of large-aperture optics in megajoule class laser systems

Menapace

2010

SPIE Proceedings

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Over the last eight years we have been developing advanced MRF tools and techniques to manufacture meter-scale optics for use in Megajoule class laser systems. These systems call for optics having unique characteristics that can complicate their fabrication using conventional polishing methods. First, exposure to the high-power nanosecond and sub-nanosecond pulsed laser environment in the infrared (>27 J/cm 2 at 1053 nm), visible (>18 J/cm 2 at 527 nm), and ultraviolet (>10 J/cm 2 at 351 nm) demands ultra-precise control of optical figure and finish to avoid intensity modulation and scatter that can result in damage to the optics chain or system hardware. Second, the optics must be super-polished and virtually free of surface and subsurface flaws that can limit optic lifetime through laser-induced damage initiation and growth at the flaw sites, particularly at 351 nm. Lastly, ultra-precise optics for beam conditioning are required to control laser beam quality. These optics contain customized surface topographical structures that cannot be made using traditional fabrication processes. In this review, we will present the development and implementation of large-aperture MRF tools and techniques specifically designed to meet the demanding optical performance challenges required in largeaperture high-power laser systems. In particular, we will discuss the advances made by using MRF technology to expose and remove surface and subsurface flaws in optics during final polishing to yield optics with improve laser damage resistance, the novel application of MRF deterministic polishing to imprint complex topographical information and wavefront correction patterns onto optical surfaces, and our efforts to advance the technology to manufacture largeaperture damage resistant optics.

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Inertial Fusion

Morse¹

2018

Graduate Texts in Physics

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NIF final optics system: frequency conversion and beam conditioning

Cited by 80 publications

References 10 publications

MRF applications: on the road to making large-aperture ultraviolet laser resistant continuous phase plates for high-power lasers

MRF applications: on the road to making large-aperture ultraviolet laser resistant continuous phase plates for high-power lasers

Developing magnetorheological finishing (MRF) technology for the manufacture of large-aperture optics in megajoule class laser systems

Inertial Fusion

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