The Lawrence Livermore National Laboratory is home to the world’s largest laser system, the National Ignition Facility (NIF). The NIF with its 192 beam lines and over 40,000 optics has been an engine of innovation for lasers and optics technologies for the last couple of decades. The Lasers and Optics intellectual property portfolio is the culmination of the many groundbreaking developments in high energy, high peak power and ultrashort pulse laser system design and operation, including technologies related to Laser Diodes, Fiber & Disk Lasers, Compact Telescopes, High Damage Threshold Gratings, High Power Optical Components and their Fabrication and Coating Techniques. The thrust of the research and development at the NIF has been to realize novel approaches for laser systems, optical components and their applications that are more compact and higher efficiency while reliably delivering ever higher energy and peak power capabilities required in the furtherance of LLNL’s missions in Stockpile Stewardship and High Energy Density Science.
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It’s the late 1990s. Lloyd Hackel and Brent Dane are researchers in Lawrence Livermore National Laboratory’s (LLNL) laser science and technology program.
They’re developing laser technology for X-ray lithography and satellite imaging research for the Department of Defense when the phone rings. On the line is Curtiss-Wright’s Metal Improvement Company (MIC) asking about something Hackel and Dane haven’t worked on before: high-peak-power laser peening for commercial applications in manufacturing.
This is an example of how LLNL’s mission-focused work advancing national security can lead to technology spin-offs with commercial importance through the Innovation and Partnerships Office (IPO).
For more, watch the YouTube video.
Decades of cutting-edge laser, optics and plasma physics research at Lawrence Livermore National Laboratory (LLNL) played a key role in the underlying science that the semiconductor industry uses to manufacture advanced microprocessors. Now a new research partnership led by LLNL aims to lay the groundwork for the next evolution of extreme ultraviolet (EUV) lithography, centered around a Lab-developed driver system dubbed the Big Aperture Thulium (BAT) laser.
LLNL plasma physicists, Brendan Reagan and Jackson Williams, are the project’s co-lead principal investigators. The project includes scientists from SLAC National Accelerator Laboratory; ASML San Diego; and the Advanced Research Center for Nanolithography (ARCNL), a public-private research center based in the Netherlands.
Starris: Optimax Space Systems and Lawrence Livermore National Laboratory (LLNL) have entered a commercialization partnership for LLNL’s patented monolithic telescope technology, which accelerates rapid deployment of modular optical designs for high-resolution or high-sensitivity space imagery.
Starris has collaborated over the last decade with LLNL’s Space Program to develop the monolithic telescope technology and will manufacture — at scale and with customization options — the precision-fabricated optical lens that forms the image in the telescope. The collaboration with LLNL is now extended via a government-use license for commercializing the technology through LLNL’s Innovation and Partnerships Office (IPO).
Powder atomic layer deposition process is used to coat nanopowders of host materials (e.g. yttrium aluminum garnet) with optically active neodymium organometal precursor followed by O2/O3 RF plasma to convert to a single layer of Nd2O3. The process can be repeated to build arbitrarily thick layers with custom doping profiles and followed by post-…
This invention proposes using a pulse laser configured to generate laser pulses and a controller for controlling operation of the pulse laser. The controller is further configured to control the pulse laser to cause the pulse laser to generate at least one of the laser pulses with a spatiotemporally varying laser fluence over a duration of at least one of the laser pulses. The spatiotemporally…
LLNL researchers have developed a high average power Faraday rotator that is gas-cooled and uniquely designed to dissipate heat uniformly so that it does not build up in the optical component and affect its performance. The Faraday rotator material is sliced into smaller disks like a loaf of bread so that high speed helium gas can flow between the slices. With this highly efficient…
This invention discloses a method to minimize transient variations in the wavelength- and/or pointing-behavior of an optic, without requiring a reduction in its thermal resistance, optical absorption, or operating irradiance. The invention employs a combination of a time-varying heat source and time-varying thermal resistance and/or heat sink temperature to achieve temperature stability of the…
This invention concerns a new type of optic: a transient gas or plasma volume grating produced indirectly by small secondary lasers or directly by nonlinear processes using the primary beams themselves. When used in conjunction with advantageously placed shielding it offers a means of protecting the final optical components of a high-repetition-rate IFE facility. These transmission optics are…
The new LLNL technique works by transiently removing and trapping concrete or rock surface material, so that contaminants are confined in a manner that is easy to isolate and remove. Our studies suggest that 10 m2 of surface could be processed per hour. The technique easily scales to more surface/hr.