Nanotechnologies for Composites, Surface Coatings and Sensors
ION Publishing Ltd
February 1, 2007 137 Pages - SKU: IONT1537364
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This report describes nanotechnologies, nanomaterials, nanotechnology companies, universities and research centres related to nanotechnologies for Composites, Surface Coatings and Sensors.
Including:
- In depth profiles of R&D and technologies under commercialization
- Short, Medium and Long-Term Application Areas
- Full Contact Details (Company/Research Centre Name, Main Contact Person, Phone, Email)
These cutting edge reports allow access to the latest R&D and commercial applications in nanotechnology.
Areas covered include:
- Cutting tools and enhanced metals
- Nanocomposite containers for long term storage of chemicals
- Self-healing composites
- Fatigue resistant materials
- Smart surfaces/Coatings
- Chemically/electrically tuned carbon nanotube composites as effective self cleaning materials and molecular sensors
- Ultra-Sensitive Chemical Sensor Coatings
- Dendrimer/nanoparticle assemblies as chemical toxin deactivation coatings
- Wear and Corrosion Resistant Coatings
- Carbon nanotube and fibre based composites
- Tunable, adaptive, self-healing and stress-smart sensing systems
- Super Strong Functional Composite Coatings and Textiles Based on Carbon Nanotubes
- Sensory/responsive textiles
- Cut resistant materials
- BioSensors
- Sensor Probes
- Carbon Nanotube Sensors
- Nanotube Sensor Networks
- Smart dust
- Boron isotopes based semiconductors as sensitive elements
- Nanoporous Materials for multifunctional sensors and devices
- RFID Hydrogen Sensors
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- 1 INTRODUCTION
- 2 TECHNOLOGY PROVIDERS
- 2.1 UNIVERSITIES
- 2.1.1 University 1 United States: Reinforcement of polymeric resin with nanoclay platelets resulting in lightweight materials with enhanced mechanical and thermal properties for next generation aerospace composites
- 2.1.2 University 2 United States: New methods and processes to synthesize new nanocomposite coatings
- 2.1.3 University 3 United States: Nanometre inorganic fillers in organic (polymeric) materials
- 2.1.4 University 4 United States: Chemically/electrically tuned carbon nanotube composites as effective self cleaning materials and molecular sensors
- 2.1.5 University 5 United States: Catalysis, photochemical reactions at the nanoparticle surface such as tiles, magnetic nanoparticles
- 2.1.6 University 6 United States: Photovoltaics, sensors and radiation shielding using nanocomposite materials
- 2.1.7 University 7 United States: Nanoscale structures for hydrogen detection and RFIDtag types of interrogation systems
- 2.1.8 University 1 United Kingdom: Degradation behaviour of nanocrystalline metals
- 2.1.9 University 2 UK: Titanium Nitride as a surface coating for erosion/corrosion protection and wear resistance
- 2.1.10 University 3 UK: Structured surfaces with novel functionality for micro-sources and sensors
- 2.1.11 University 4 UK: Sol-gel based coatings
- 2.1.12 University 5 UK: Novel coating systems and chromium alternatives that will reduce the environmental impact of automobiles
- 2.1.13 University 6 UK: Scratch-resistant coatings & polymers
- 2.1.14 University 7 UK: Surface functionalization and characterization particularly using self-assembled monolayers for controlling wetting and adhesion
- 2.1.15 University 8 UK: Titanium based nanomaterials for engine applications
- 2.1.16 University 9 UK: Luminescence ceramic coatings where the luminescence is introduced by doping with rare earth ions
- 2.1.17 University 10 UK: Wear resistant coatings
- 2.1.18 University 11 UK: Coatings and polymeric structures used in specialist structural and other applications
- 2.1.19 University 12 UK: Photocatalytic titania; Surface modification for glass, ceramics, worktops and all textiles
- 2.1.20 University 13 UK: Polyurethanes containing nano-cages
- 2.1.21 University 14 UK: Self-healing nanomaterials
- 2.1.22 University 15 UK: Nanostructured intelligent surfaces
- 2.1.23 University 16 UK: Photocatalytic protective anti-fouling coatings
- 2.1.24 University 17 UK: ‘Stealth particles’ fabricated and coated with surfactants and phosolipids
- 2.1.25 University 18 UK: Nanostructured metal oxides for photocatalytic treatment of water
- 2.1.26 University 19 UK: Synthesis and characterisation of composite metal nanoparticles for magnetic storage media
- 2.1.27 University 20 UK: Carbon nanotube composites; Responsive and smart surfaces
- 2.1.28 University 21 UK: New composite materials based on carbon nanotubes
- 2.1.29 University 22 UK: Biosensor systems
- 2.1.30 University 23 UK: Biodegradation of soil pollutants
- 2.1.31 University 24 UK: Development of miniaturised nanosensors incorporating wireless technology that can be retrospectively embedded into a range of building components
- 2.1.32 University 25 UK: Adhesion on surfaces
- 2.1.33 University 1 Italy: Nanostructured metallic coatings with higher mechanical and corrosion resistance properties than traditional structured coatings
- 2.1.34 University 2 Italy: Thermal spraying of ceramics and cement materials (HVOF, plasma techniques) for wear, corrosion and high temperature resistance
- 2.1.35 University 3 Italy: Thin films and surface-anchorages
- 2.1.36 University 4 Italy: Production of nanostructured solid powders and nanoparticle films by compartmentalised solution thermal spraying
- 2.1.37 University 5 Italy: PECVD deposition of organosilicon coatings
- 2.1.38 University 6 Italy: Anti-microbial treatments for cellulosic and synthetic fibres with silver
- 2.1.39 University 1 South Korea: Bacteriostasis of nanosized colloidal silver on polyester nonwovens
- 2.1.40 University 1 Denmark: The use of electrodes to destroy unwanted organic compounds and to monitor wear and corrosion
- 2.1.41 University 2 Denmark: Surface modification with coatings based upon nano/microstructures, which eliminate biofilms
- 2.1.42 University 1 Czech Republic: Scratch-resistant surfaces
- 2.1.43 University 1 Israel: Method for the insertion of catalytic nanoparticles into mesoporous materials
- 2.1.44 University 1 France: Design, synthesis and characterization of novel materials containing nanometric phases, in the form of powders and dense materials
- 2.1.45 University 1 Ireland: Generic route to polymer reinforcement via the preparation of polymer-functionalized nanotubes using an organometallic approach
- 2.1.46 University 1 Brazil: Deposition process for coating anti-etching based in plasma process and polymer deposition
- 2.1.47 University 1 Japan: Method for forming a water-repelling, oil-repelling anti-staining chemically adsorbed film
- 2.1.48 University 1 Georgia: Boron isotopes based semiconductors as sensitive elements
- 2.1.49 University 1 Austria: Catalysis
- 2.1.50 University 1 Hong Kong: Photocatalysis
- 2.2 COM
- 2.2.1 Company 1 Japan: Photocatalysis
- 2.2.2 Company 1 United States: Organic-inorganic nanocomposites for anti-reflection coating for LCDs and anti-scratch coatings
- 2.2.3 Company 2 United States: Nanosized copper and silver for anti-fungal, anti-bacterial, and anti-microbial dressings and surfaces
- 2.2.4 Company 3 United States: Hybrid coating that provides corrosion protection for aluminium allo
- 2.2.5 Company 4 United States: Nanocrystalline metal oxide powders for coating applications
- 2.2.6 Company 5 United States: Intelligent polymers to control permeation, adhesion and viscous flow in response to small temperature changes
- 2.2.7 Company 6 United States: Nanomaterials for surface and air space decontamination, protective textiles, air and water purification and filtration
- 2.2.8 Company 7 United States: Inorganic fullerene-like (IF) nanospheres and nanotubes for semiconducting post-silicon era electronics
- 2.2.9 Company 8 United States: Carbon nanofibres
- 2.2.10 Company 9 United States: Fibre-spinning technology to coat filter fabric (non-woven) and or paper ...
- 2.2.11 Company 1 South Korea: Nanofibres with anti-bacterial properties for garments
- 2.2.12 Company 1 The Netherlands: Nanocomposite coatings and bulk materials for mechanical strength (scratch resistance, impact resistance); Anti-stick and low friction coatings
- 2.2.13 Company 2 Netherlands: Silicon-based chips/sensors for pH and pressure
- 2.2.14 Company 1 Belgium: Plasma treatments for functionalization of surfaces
- 2.2.15 Company 2 Belgium: Nanopowders of diamond and filtration
- 2.2.17 Company 4 Belgium: Friction and wear testing of thin coatings
- 2.2.18 Company 5 Belgium: Energetic ion track technology
- 2.2.19 Company 1 United Kingdom: Ultra-sensitive chemical sensor coatings
- 2.2.20 Company 2 UK: Fibre-reinforced and nanoclay filled materials
- 2.2.21 Company 3 UK: Film catalysts and surface agents
- 2.2.22 Company 4 UK: Functional coatings which include liquid repellent coatings, decontamination coatings and sensor coatings
- 2.2.23 Company 6 UK: Nanocomposite coating with tailored functional performance
- 2.2.24 Company 7 UK: Photoactive films
- 2.2.25 Company 8 UK: Biological marking - fluorescent imaging of cells and other biological structures; Quantum Dots.
- 2.2.26 Company 9 UK: Catalytic system that provides a novel and simple approach to the killing and removal of bacterial biofilms
- 2.2.27 Company 10 UK: Photocatalytic coatings for anti-soiling and anti-bacterial activity
- 2.2.28 Company 11 UK: High-purity single and multi-wall carbon nanotubes
- 2.2.29 Company 12 UK: Ultra-thin polymer coatings for textiles, plastics, glass, and metal
- 2.2.30 Company 13 UK: Super-repellent coatings
- 2.2.31 Company 14 United Kingdom: Anti-microbials that can be used on textiles without impairing the water absorbency or softness of the product
- 2.2.32 Company 15 UK: Improved switch and sensor designs, textile switches and sensors, and electronic noses
- 2.2.33 Company 16 UK: Anti-biocidal and anti-bacterial coatings produced via nanostructured thin films and coatings
- 2.2.34 Company 1 Sweden: Functional textile sensor material for a wide variety of applications
- 2.2.35 Company 2 Sweden: Production of nanoparticulate additives for improvement of combustion and preventing of fouling and corrosion
- 2.2.36 Company 3 Sweden: Nanostructured thermoelectric materials
- 2.2.37 Company 1 China: Water and oil repellent textiles via nanoscale functional surfaces
- 2.2.38 Company 1 Israel: Highly chemical resistant polymer materials
- 2.2.39 Company 2 Israel: Nanosilver based waterbourne biocide coatings
- 2.2.40 Company 1 Germany: Corrosion protection with sol gel coatings
- 2.2.41 Company 2 Germany: Nanomaterials for anti-stick coatings, scratchproof systems and corrosion protection
- 2.2.42 Company 3 Germany: Protection of metal surfaces from fingerprints by means of a thin nanocomposite
- 2.2.43 Company 5 Germany: Multifunctional coatings for medical applications
- 2.2.44 Company 6 Germany: Nanoparticle modification
- 2.2.45 Company 7 Germany: Nanoparticle coatings for architecture, automotive and life sciences
- 2.2.46 Company 8 Germany: Nanoparticles for cosmetics
- 2.2.47 Company 9 Germany: Nanocomposites
- 2.2.48 Company 1 France: Nanoscale powders in polymer for use in the textile industry
- 2.2.49 Company 2 France: Surface structures as sensors for water/air pollutants
- 2.2.50 Company 3 France: Carbon nanotubes for reinforcement and protection
- 2.2.51 Company 4 France: Functionalization of carbon nanotubes-applications to composites materials and sensors
- 2.2.52 Company 1 Spain: Hydrophobic corrosion resistant coatings
- 2.2.53 Company 1 Australia: Organic/inorganic nanohybrid films
- 2.2.54 Company 1 Ireland: Surface engineering technology with multi-sectoral application
- 2.3 RESEARCH CENTRES
- 2.3.1 Research Centre 1 Israel: Smart dust
- 2.3.2 Research Centre 1 Finland: Hydrophilic Surfaces
- 2.3.3 Research Centre 1 Norway: Nano structured hybrid and polymer materials for catalysis, selective separation and purification, chemical and biological sensing as well as optical communications
- 2.3.4 Research Cente 1 Russia: Silica nanohybrid materials, creation nanosorbents with the unequal functionality and textural characteristics
- 2.3.5 Research Centre 1 France: Self-assembled low molecular weight compounds in solution or at interfaces
- 2.3.6 Research Centre 1 Italy: Hybrid nanoporous materials based on SBA-16 with varying silica concentrations by simple and cost effective sol-gel process
- 2.3.7 Research Centre 1 Spain: Modification of wettability & protein adsorption properties...
- 2.3.8 Research Centre 2 Spain: Surface modification with biomolecules (peptides, enzymes, oligonucleotides)
- 2.3.9 Research Centre 3 Spain: Development of chemical transducers based on different transduction principles and/or signal propagation media
- 2.3.10 Research Centre 1 Denmark: Polymer based sensors and sensor networks
- 2.3.11 Research Centre 2 Denmark: Surface modification with coatings based upon nano/microstructures, which eliminate biofilms; Icephobic surfaces and non stick surfaces
- 2.3.12 Research Centre 1 Ireland: SiO Sol-gel nanostructured films for chromate replacement in aerospace
- 2.3.13 Research Centre 1 Germany: Multifunctional nanocoatings
- 2.3.14 Research Centre 2 Germany: Stimuli-Responsive polymer coatings polymers
- 2.3.16 Research Centre 4 Germany: Functional coating systems for architectural textiles
- 2.3.17 Research Centre 5 Germany: Nanoscale inorganic-organic hybrid materials
- 2.3.18 Research Centre 6 Germany: Photocatalytic effect of TiO
- 2.3.19 Research Centre 1 China: Photocatalytic materials including photocatalytic coating, light-cleaning glass and ceramic
- 2.3.20 Research Centre 2 China: Super hydrophobic aligned carbon nanotube films and nanofibres
- 2.3.21 Research Centre 1 Sweden: Nano structured intelligent surfaces for protective clothing
- 2.3.22 Research Centre 1 Switzerland: Thermal insulating coatings
- 2.3.23 Research Centre 1 Belgium: Dispersion of nanosized ceramic particles in textile coatings
- 2.3.24 Research Centre 1 United States: Surface modification of textiles
- 3 GLOSSARY OF TERMS
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