NCD

(redirected from Nanocrystalline Diamond)
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AcronymDefinition
NCDNational Council on Disability
NCDNational Coverage Determination
NCDNational Clinical Database (Japan)
NCDNative Circuit Description (file format)
NCDNational Capacity Development (various locations)
NCDNatural Cellular Defense
NCDNorton Change Directory
NCDNero Cover Designer Document
NCDNetwork Computing Devices
NCDNeighborhood Commercial District (various locations)
NCDNon-Communicable Disease
NCDNew Concept Development (various organizations)
NCDNational Capital District
NCDNo Claim Discount (auto insurance)
NCDNational Condom Day (safe sex awareness)
NCDNon-Convertible Debenture
NCDNorton Change Directory (Norton Utilities)
NCDNeedle Chest Decompression (medical procedure)
NCDNon-Contagious Disease
NCDNegotiable Certificate of Deposit
NCDNanocrystalline Diamond (synthetic)
NCDNational Center for Digitization (Serbia)
NCDNippon Computer Dynamics Co., Ltd. (Japan)
NCDNigerian Content Division (est. 2005)
NCDNew Castle Disease (viral disease of chicken)
NCDNo Claims Declaration (insurance)
NCDNorth Central Division (USACE)
NCDNational Control Devices
NCDNormalized Compression Distance
NCDNon Crystalline Diffraction
NCDNanochromics Display (Ntera Ltd; Ireland)
NCDNational Catechetical Directory
NCDNaval Construction Division
NCDNonlinear Control Design
NCDNacho Cheese Doritos (food)
NCDNutrition Care Division
NCDNon-Carbonated Drink (beverage industry)
NCDNo Computed Data
NCDNo Can Do
NCDNew Club Development (New York University)
NCDNew Collegiate Division (University of Chicago; Chicago, IL)
NCDNo Cloud Detected (meteorology)
NCDNo Cell Delineation (ITU-T)
NCDNew Currency Design (US Bureau of Engraving and Printing)
NCDNon Coherent Detection
NCDNational Council on Drugs
NCDNewport Chemical Depot (Newport, Indiana)
NCDNational Calamity Contingency Duty (India)
NCDNetwork Copy Detection (Aldus Corp.)
NCDNon-Chemical Device (water conditioning)
NCDNon-Classified Drainage (forestry stream classification)
NCDDeputy Comptroller of the Navy
NCDNetwork Control Division
NCDNearly Completely Decomposability
NCDNetwork Control Device
NCDNaval Contracting Directive
NCDNorthland: A Church Distributed
NCDNode Connectivity Diagram
NCDNumber Column Density
NCDNetwork Call Delivery (Cisco)
NCDNetwork Connectivity Device
NCDNever Can Deliver
NCDNotice of Credit Due (US Navy)
NCDNetwork Call Distribution
NCDNo Confirmed Date
NCDNon-Compliant Device
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References in periodicals archive ?
[24] Show Y., Witek M.A., Sonthalia P., Swain G.M.: "Characterization and electrochemical responsiveness of boron-doped nanocrystalline diamond thin-film electrodes".
Nanocrystalline diamond (NCD) surface was found to be useful for bone regeneration purpose, as osteoblast cell adhered well on the diamond surface (11) and it was nontoxic to fibroblast cells (12).
The diamond nanoparticles suspension was further employed in diamond nucleation enhancement step for nanocrystalline diamond films growth using spin-coating technique.
Therefore, we present here the fabrication of nanocrystalline diamond (NCD) thin film based UV detectors using metal-semiconductor-metal structure, aiming at higher production rate and higher quality of the films deposition for improving the efficiency and repeatability/reproducibility of the devices.
A complementary metal-oxide semiconductor (CMOS) compatible n-type nanocrystalline diamond-based material, Miraj Diamond is made possible by a new approach to n-type doping while simultaneously allowing integration with existing CMOS platforms through low-temperature deposition of nanocrystalline diamond thin films at 400 C.
With the debut of the Miraj Diamond[TM] platform, AKHAN Technologies has developed a new patent-pending process in which n-type diamond material is created over silicon with previously undemonstrated characteristics, such as shallow ionization energy of 250 meV, high carrier mobility (greater than 1000 cm2/Vs in nanocrystalline diamond thin films), no graphitic phases, and previously undemonstrated performance in low voltage high current diode device applications (900 A/mm2 current density at +2V forward bias).
Nanocrystalline diamond has recently been considered for use in preventing microbial growth (Leis et al., 2010).
They cover diamonoid hydrocarbons; carbon nanotubes as electron sources; nanocrystalline diamond coatings for advanced acoustic devices; depositing nanocrystalline diamond by Ar/H2/CH4 microwave discharges; the growth, properties, and applications of thick self-standing blocks of multi-walled carbon nanotubes; chemical vapor deposition as a route to microcrystalline, nanocrystalline, ultrananocrystalline, and single-crystal diamond films; the synthesis, atomic structures, and properties of carbon nanostructured materials; chemical vapor deposited diamond for thermoplastic injection molds; composites of carbon nanotubes and polymers for biomedical applications; and nanostructured coatings.
Research has been performed for approximately six years to develop a crystal vapor deposition process using nanocrystalline diamond. The process involves the application of a high temperature plasma deposition.