Not exact matches
At Oakley, Jannard had thrown himself into the creative engineering process, enlisting technologies such as liquid
laser prototyping and electron - beam gun - vapor
deposition in his quest to make state -
of - the - art sunglasses.
«New
deposition technique enhances optoelectronic properties
of lasers: Yield and efficiency
of gallium nitride - based vertical - cavity surface - emitting
lasers, a type
of laser with potential applications in heads - up displays, automotive headlights, visible light data transmission, improved.»
A simple new electron - beam multilayer
deposition technique for creating intracavity contacts — an important component
of gallium nitride - based (III - nitride) vertical - cavity surface - emitting
lasers (VCSELs)-- not only yields intriguing optoelectronic properties but also paves the way for others entering this realm
of research.
Jonathan Petrie led the epitaxial synthesis
of strained oxide materials and catalytic testing, and Tricia Meyer assisted thin film
deposition using a technique that employs a high - power excimer
laser to vaporize material and deposit it as high - quality thin films under precisely controlled conditions.
With pulsed
laser deposition (PLD) you can achieve controlled growth
of thin layers
of certain materials.
One way would have been to use an inflow
of gaseous fluoride to coat the surface
of the KMgF3 thin film, but instead the team discovered a safer route to fabricating it with pulsed
laser deposition — a way
of layering thin films
of chemicals onto surfaces through irradiation with a focused
laser beam.
Dr. Kaspar's research interests include the epitaxial growth (via oxygen - plasma - assisted molecular beam epitaxy or pulsed
laser deposition) and structural characterization
of metallic and metal oxide films.
His film
deposition methods
of choice are molecular beam epitaxy and off - axis pulsed
laser deposition, assisted by activated oxygen from an oxygen plasma generator or ozone.
The company's strategy is to expand the business into the life sciences arena, where nanotechnology and biotechnology intersect This involves the combination
of core technologies in areas such as low temperature, high magnetic field and ultra-high vacuum environments; Nuclear Magnetic Resonance; X-ray, electron,
laser and optical based metrology; atomic force microscopy; optical imaging; advanced growth,
deposition and etching.
Combinatorial
depositions with intentional and well - controlled continuous gradients in process parameters (composition, temperature, film thickness, nanoparticle size etc): wide range
of thin film chemistries in separate chambers (metals, oxides, nitrides, sulfides); physical vapor
deposition techniques (sputtering, pulsed
laser deposition); different substrates and supports (glass, metals, glassy carbon, etc).
(b) The ability to grow high quality film and bulk samples by a variety
of growth techniques including sputtering, pulse
laser deposition (PLD), evaporation, bulk ceramic processing, hydrothermal growth and HIP and Hot Pressing processing can be done under an extremely broad range
of temperature and oxygen partial pressure as suggested by theory and experiment.
As for the printer, nearly any good
laser printer will do — until you are trying to print out four copies
of all your exhibits the night before a
deposition or trial.