Lightwave Electronics Corporation

A Lightwave Electronics model 122 microprocessor controlled Nd:YAG laser, produced in about 1990. This laser was based on the nonplanar ring oscillator design. This continuous-wave, single-frequency laser was aimed at the laboratory market. Lightwave Electronic's biggest market was for OEM lasers, (lasers used as components in other manufacturer's systems), primarily Q-switched lasers for micromachining.

Lightwave Electronics Corporation was a developer and manufacturer of diode-pumped solid-state lasers, and was a significant contributor to the creation[1] and maturation of this technology. Lightwave Electronics was a technology-focused company, with diverse markets,[2] including science and micromachining. Inventors employed by Lightwave Electronics received 51 US patents,[3] and Lightwave Electronics products were referenced by non-affiliated inventors in 91 US patents.[4]

Lightwave Electronics was a California corporation which was founded in 1984. The primary founders were Robert L. Mortensen, a former executive at the laser manufacturer Spectra Physics; Dr. Robert L. Byer, a professor of Applied Physics at Stanford University; and the Newport Corporation, then headed by Dr. Milton Chang. Mortensen was president at the company’s founding, and he served as president for almost 15 years.[5] Phillip Meredith was president from 2000 until the sale of the company in 2005.[6] JDS Uniphase Corporation (JDSU, now Lumentum, stock ticker LITE) purchased Lightwave in 2005, for $65M.[7][8] At that time, the company had 120 employees. The company was located in Mountain View, California.

Products

In the scientific community, Lightwave Electronics was best known for single-frequency lasers based on the nonplanar ring oscillator design.[9] These lasers operated at the wavelengths of 1064 nm and 1319 nm, and were based on the laser material neodymium-doped yttrium-aluminum garnet (Nd:YAG). The first-generation Laser Interferometer Gravitational Wave Observatory (LIGO) was based on these lasers, operating at 1064 nm.[10] Two Lightwave nonplanar oscillators were launched into space in 2004 as components of NASA’s Tropospheric Emission Spectrometer, an earth-observing satellite instrument which was still operational in 2015.[11] Lightwave Electronics produced a visible (532 nm) laser source based on frequency doubling the output of a nonplanar ring oscillator.[12] The nonlinear material used was magnesium-doped lithium niobate. Another member of the nonplanar ring product family was an “injection seeding” system which was used to enforce single-frequency oscillation in 1-joule-level lamp-pumped Q-switched lasers, improving the utility of those lasers for quantitative spectroscopy.[13][14] This injection seeding system was the first Lightwave Electronics product with significant sales.

Lightwave Electronics' first significant success in industrial markets was a series of acousto-optically Q-switched lasers[15][16] at 1047 nm, based on neodymium-doped yttrium lithium fluoride (Nd:YLF), and at 1342 nm, based on neodymium-doped yttrium orthovanadate, which were used to improve yield in semiconductor memory manufacturing. For about 2 decades, from about 1988 to 2008, semiconductor manufacturers used the Lightwave Electronics miniature Q-switched lasers in the link blowing step[17] during the production of the majority of the world’s dynamic random-access memory chips. These miniature Q-switched lasers were in systems built by Electro Scientific Industries, GSI, and Nikon.

Also of significant industrial importance was a series of internally frequency converted Q-switched lasers, with 2 to 20 Watt of ultraviolet output at 355 nm,[18] used for a variety of micromachining applications. Lightwave introduced these UV lasers in 1998. The nonlinear frequency converting material was lithium triborate (LBO). Lightwave’s Q-switched multi-watt UV lasers emitted longer pulses than competing lasers and allowed effective processing of materials,[19] probably by melting as opposed to ablation (vaporization), thus lowering the power needed for removing material in operations such as laser-drilling small holes in circuit boards, or laser-cutting circuit boards[20]

For a few years (circa 1996), Lightwave Electronics produced an acousto-optically mode-locked laser with low frequency jitter and drift. The most significant application was for high-speed measurements of voltages as a step in the design and improvement of integrated circuits.[21] A distinct line of mode-locked lasers produced ultraviolet output at 355 nm, used for fluorescence excitation in flow cytometry applications.[22] Mode-locking was passive, using a semiconductor saturable absorber. In the late 1990s Lightwave Electronics produced a Nd:YAG laser internally frequency doubled to 532 nm with potassium titanyl phosphate (KTP), used in ophthalmology.

Technology

Photograph shows the technique used to mount optics in a Lightwave Electronics single-frequency frequency-doubled laser. The optic in the left foreground is bonded with a thin layer of UV-curing adhesive to a support block, also made of glass, which is bonded to the platform. This design approach allows 5 degrees of freedom for the optic, with a thin adhesive bond.[23]

Early products benefited from relationships with Stanford University and other Bay Area laboratories. The nonplanar ring oscillator technology was invented at Stanford University,[24] and the patent[25] was licensed to Lightwave Electronics. The injection seeding product was developed with cooperation from SRI International and Sandia National Laboratories (Livermore).[13][14]

Lightwave Electronics is listed as the assignee on 51 United States patents.[3] Several of these relate to active laser stabilization, including stabilization of optical frequency,[26] of intensity,[27] and of pulse repetition rate[28] and pulse energy.[29] Another set relate to laser manufacturing techniques. Early Lightwave Electronics lasers used solder to permanently mount optics in place.[30] Later lasers, such the one shown in the figure, used adhesive cured by ultraviolet light.[23][31]

Lightwave Electronics' nonplanar ring lasers, and the infrared Q-switched lasers used for DRAM production, were "end-pumped," meaning that the beam from the semiconductor laser pump was co-axial with the beam of the pumped laser. Later lasers, including all of the 355 nm lasers, were side-pumped. Small-diameter (<2 mm) Nd:YAG rods were pumped by powerful (>20 watt), large-aperture semiconductor lasers placed alongside the rods. Lightwave Electronics developed and patented a design enabling efficient side-pumping of a laser while maintaining diffraction-limited output.[32] The end-pumped pumped products were limited in power to less than 1 watt, while side-pumped products have exceeded 20 watts.

Lightwave Electronics made extensive use of the Small Business Innovation Research (SBIR) Program, established in 1982.

Successor Companies

Spin-off companies from Lightwave Electronics Corporation include Electro-Optics Technology, of Traverse City MI; Time-Bandwidth Products of Zurich, Switzerland, now a part of Lumentum; and Mobius Photonics,[33] acquired by IPG Photonics. Products sold by Lumentum in 2015 which derive from Lightwave Electronics Corporation products are: the NPRO 125/126 series nonplanar ring lasers, the Q-series Q-switched 355 nm lasers, and the Xcyte quasi-continuous 355 nm lasers.[34]

References

  1. Jeff Hecht, "Photonic Frontiers: Laser diodes: Looking back/Looking forward: Laser diodes have come a long way and brought five Nobel prizes," Laser Focus World, April 2015
  2. Anne Gibbons, “Optics Boom Spawns Need For More Experts,” The Scientist, May 1, 1989
  3. 1 2 Search US Patents with Assignee Name = Lightwave Electronics
  4. Search US Patents with Description/Specification = Lightwave Electronics and Assignee Name ≠ Lightwave Electronics
  5. Reuters, "Mobius Photonics Names Robert L. Mortensen CEO," Sept 15, 2009.
  6. Bloomberg, Company Overview of Lightwave Electronics Corporation, Executive Profile, Phillip Meredith.
  7. Laser Focus World, "JDSU buys Lightwave Electronics for $65 million," March 21, 2005.
  8. JDS Uniphase Corporation's 10-K form, filed Aug. 29, 2007, states that the purchase was “for approximately $67.2 million in cash.”
  9. RP Photonics Encyclopedia of Laser Physics (online), "Nonplanar Ring Oscillators,"
  10. https://www.advancedligo.mit.edu/diode_laser.html
  11. Deep Space Optical Communications, edited by Hamid Hemmati, page 444-445. Wiley.
  12. D. C. Gerstenberger, G. E. Tye, and R. W. Wallace, "Efficient second-harmonic conversion of cw single-frequency Nd:YAG laser light by frequency locking to a monolithic ring frequency doubler," Opt. Lett. 16, 992-994 (1991)
  13. 1 2 Randal L. Schmitt and Larry A. Rahn, "Diode-laser-pumped Nd:YAG laser injection seeding system," Appl. Opt. 25, 629-633 (1986)
  14. 1 2 M. J. Dyer, W. K. Bischel, and D. G. Scerbak, "Injection locking of Nd:YAG lasers using a diode-pumped cw YAG seed laser," in Conference on Lasers and Electro-Optics, Vol. 14 of OSA Technical Digest (1987), paper WN4.
  15. US Patent 5,130,995, “Laser with Brewster angled-surface Q-switch aligned co-axially.”
  16. William M. Grossman, Martin Gifford, and Richard W. Wallace. "Short-pulse Q-switched 1.3-and 1-μm diode-pumped lasers." Opt. Let. 15, 622-624 (1990)
  17. Edward J. Swenson ; Yunlong Sun and Corey M. Dunsky "Laser micromachining in the microelectronics industry: a historical overview", Proc. SPIE 4095, Laser Beam Shaping, 118 (October 25, 2000)
  18. US Patent 5,850,407, “Third-harmonic generator with uncoated brewster-cut dispersive output facet.”
  19. Rizvi, Nadeem H., et al. "Micromachining of industrial materials with ultrafast lasers." Proc. ICALEO. Vol. 15. No. 1. 2001.
  20. L. Rihakova and H. Chmelickova, “Laser Micromachining of Glass, Silicon, and Ceramics,” Advances in Materials Science and Engineering, vol. 2015
  21. US Patent 6,496,261, "Double-pulsed optical interferometer for waveform probing of integrated circuits."
  22. Farr, Christina, and Stuart Berger. “Measuring Calpain Activity in Fixed and Living Cells by Flow Cytometry.” Journal of Visualized Experiments : JoVE 41 (2010): 2050. PMC. Web. 28 Nov. 2015.
  23. 1 2 US Patent 6,366,593, "Adhesive precision positioning mount."
  24. Thomas J. Kane and Robert L. Byer, "Monolithic, unidirectional single-mode Nd:YAG ring laser," Opt. Lett. 10, 65-67 (1985)
  25. US Patent 4,578,793, "Solid-state non-planar internally reflecting ring laser."
  26. US Patent 4,829,532, "Piezo-electrically tuned optical resonator and laser using same."
  27. US Patent 5,757,831, "Electronic suppression of optical feedback instabilities in a solid-state laser."
  28. US Patent 6,909,730, "Phase-locked loop control of passively Q-switched lasers."
  29. US Patent 5,982,790, "System for reducing pulse-to-pulse energy variation in a pulsed laser."
  30. US Patent 4,749,842, "Ring laser and method of making same."
  31. US Patent 6,320,706, "Method and apparatus for positioning and fixating an optical element."
  32. US Patent 5,774,488, "Solid-state laser with trapped pump light."
  33. Optics.org, "Start-up Spotlight: Mobius Photonics," April 11, 2008.
  34. Lumentum company website, Commercial Product Finder.
This article is issued from Wikipedia - version of the 7/2/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.