Company Filing History:
Years Active: 2001
Title: The Innovations of Danny Wayne Nightingale
Introduction
Danny Wayne Nightingale is an accomplished inventor based in Beaver Dams, NY (US). He has made significant contributions to the field of optical waveguides, particularly through his innovative patent. His work focuses on enhancing the photosensitivity of optical waveguides, which has important applications in various optical devices.
Latest Patents
Nightingale holds a patent for "Optical waveguide photosensitization." This invention is directed to a method of enhancing the photosensitivity of an optical waveguide and an optical waveguide that retains persistent UV photosensitivity after the out-diffusion of a loading gas such as hydrogen or deuterium. The method involves loading the optical waveguide with a gas to establish a baseline refractive index. By exposing the loaded waveguide to UV radiation, a change in the baseline refractive index is induced. The waveguide is then annealed to diffuse the gas and stabilize the change in refractive index. This innovative approach is particularly beneficial for designing and fabricating grating devices, tuning grating strength and wavelength, and providing accurate spatial control of waveguide photosensitivity.
Career Highlights
Nightingale's career is marked by his work at Corning Incorporated, a leading company in the field of glass and ceramics. His contributions to optical technologies have been recognized within the industry, and he continues to be an influential figure in the development of advanced optical materials.
Collaborations
Throughout his career, Nightingale has collaborated with notable colleagues, including Glenn E Kohnke and Peter Gerard Wigley. These collaborations have further enhanced his work and contributed to the advancement of optical waveguide technologies.
Conclusion
Danny Wayne Nightingale's innovative work in optical waveguide photosensitization showcases his expertise and dedication to advancing optical technologies. His contributions have significant implications for the future of optical devices and materials.