Not exact matches
Lasers and high tech
optical crystals have practical
applications in almost every field; laser scanning
devices are the interface between user and computer.
Future developments based on these results could lead to extremely miniaturized
optical circuits and
devices that could be useful for sensing and computing, among other
applications.
Researchers at McGill University have developed a new, low - cost method to build DNA nanotubes block by block — a breakthrough that could help pave the way for scaffolds made from DNA strands to be used in
applications such as
optical and electronic
devices or smart drug - delivery systems.
«On - chip
optical research is a thriving and competitive area because of its importance to manipulating classical or quantum signals in small
devices, essential for future communications, computing and information processing
applications,» said CUDOS director and co-author Ben Eggleton.
«Graphene production is obviously central to our project,» said Prof. Kinaret at the launch, but key
applications to be looked at include fast electronic and
optical devices, flexible electronics, functional lightweight components and advanced batteries.
Foreseeable
applications include integrating lasers, sensors, wave guides and other
optical components into so - called lab - on - a-chip
devices now used for disease diagnosis, screening experimental materials and drugs, DNA forensics and more.
Low - dimensional systems with well - defined features have indeed
applications as e.g. antireflection coatings, biosensors, data - storage,
optical and photovoltaic
devices, or catalysts.
The functionalized carbon nanotubes have significant prospects for further development, Doorn noted, including advances in functionalization chemistry; integration into photonic, plasmonic and metamaterials structures for further control of quantum emission properties; and implementation into electrically driven
devices and
optical circuitry for diverse
applications.
We use the power of DNA self - assembly to build and test nanophotonic
devices such as plasmonic waveguides for
application in
optical near - field communication, or for medical diagnostics and therapeutics.
Economically important
applications for semiconductor photonic
devices include
optical data recording, fiber optic telecommunications, laser printing (based on xerography), displays, and
optical pumping of high - power lasers.
My work spans research in photonic
devices,
optical systems engineering, optimization, computer vision, and biomedical
applications.
Award, which is presented to an individual who has made significant contributions to optics based on semiconductor - based
optical devices and materials, including basic science and technological
applications.
- recognizes contributions to optics based on semiconductor - based
devices and
optical materials, including basic science and technological
applications
Table of Contents: Read Only Memory (ROM) The purpose of ROM Random Access Memory (RAM) The purpose of RAM Dynamic RAM (DRAM) Static RAM (SRAM) The difference between ROM and RAM The need for virtual memory Flash memory The need for secondary storage Data capacity and calculation of data requirements Common types of storage
Optical Magnetic Solid state Suitable storage
devices and storage media for a given
application Capacity Speed Portability Durability Reliability Cost
It manufactures
optical devices, including laser diodes, photodiodes, related modules and circuitry and equipment for
applications in fiber - to - the - home, cable television, point to point communications and wireless.
He has prepared and prosecuted patent
applications for inventions in the electrical, medical, and mechanical arts, including laryngeal mask airway
devices, pressure transducers, artifact reduction filters for CT scanners, parallel processors, magnetic bearings,
optical gyroscopes, mass flowmeters, photoelectron multipliers, speech recognition systems and night vision systems.
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Device Engineer Resume
I am a dedicated research scientist with a PhD in Biomedical Engineering and post-graduation experience in developing
optical devices for
application in tumor imaging and point - of - care diagnosis.
Professional Duties & Responsibilities Biomedical and biotechnology engineer with background in design of biomaterials, biosensors, drug delivery
devices, microfrabrication, and tissue engineering Working knowledge of direct cell writing and rapid prototyping Experience fabricating nanocomposite hydrogel scaffolds Proficient in material analysis, mechanical, biochemical, and morphological testing of synthetic and biological materials Extensive experience in bio-imaging processes and procedures Specialized in mammalian, microbial, and viral cell culture Working knowledge of lab techniques and instruments including electrophoresis, chromatography, microscopy, spectroscopy, PCR, Flow cytometery, protein assay, DNA isolation techniques, polymer synthesis and characterization, and synthetic fiber production Developed strong knowledge of FDA, GLP, GMP, GCP, and GDP regulatory requirements Created biocompatible photocurable hydrogels for cell immobilization Formulated cell friendly prepolymer formulation Performed surface modification of nano - particle fillers to enhance their biocompatibility Evaluated cell and biomaterial interaction, cell growth, and proliferation Designed bench - top experiments and protocols to simulate in vivo situations Designed hydrogel based microfluidic prototypes for cell entrapment and cell culture utilizing computer - aided robotic dispenser Determined various mechanical, morphological, and transport properties of photocured hydrogels using Instron, FTIR, EDX, X-ray diffraction, DSC, TGA, and DMA Assessed biocompatibility of hydrogels and physiology of entrapped cells Evaluated intracellular and extracellular reactions of entrapped cells on spatial and temporal scales using
optical, confocal, fluorescence, atomic force, and scanning electron microscopies Designed various biochemical assays Developed thermosensitive PET membranes for transdermal drug delivery
application using Gamma radiation induced graft co-polymerization of N - isopropyl acylamide and Acrylic acid Characterized grafted co-polymer using various polymer characterization techniques Manipulated lower critical solution temperature of grafted thermosensitive co-polymer Loaded antibiotic on grafted co-polymer and determined drug release profile with temperature Determined biomechanical and biochemical properties of biological gels isolated from marine organisms Analyzed morphological and mechanical properties of metal coated yarns using SEM and Instron Performed analytical work on pharmaceutical formulations using gas and high performance liquid chromatography Performed market research and analysis for medical textile company Developed and implement comprehensive marketing and sales campaign