CVD is capable of producing high performance energy efficiency films. Such films are employed in window glazing as: Low E films where they enhance insulation properties of the glazing unit (via infra red reflection properties retaining IR energy within the building Solar Control: where sunlight energy is reflected and/or absorbed before entering the building. CVD is an attractive route to depositing such films. It is capable of high optical quality required for windows. The process also allows for a wide range of optical properties, which allow adaption of surface performance to application need. Furthermore, CVD is the only approach which has been approved for use on external window surfaces. (where 20 year life is required). CVD thus is capable of producing highly durable photo-active surfaces. CVD is also well proven as a high throughput continuous operating process, which is attractive for applications such as coating glass. In this regard it can be integrated 'on-line' with the Float glass manufacturing process.

ADMAFINE consists of nano-sized spherical oxide which has high moisture content with low surface porosity. It has good dispersability and very strong adhesion.

ADMANANO is a patented silicaceous product which is developed in liquid phase to be mixed with organic and inorganic powder to impart fluidity, filling rate, sinterability, compressibility. It can be used with inorganic pigment, functional ceramics like BaTiO3, etc.

The advanced vacuum and polymer coatings yield a wide range of characteristics from selective electromagnetic filtering to high-speed rain erosion resistance.

NanoAmor utilises various fully-scaled processing technologies to manufacture a wide range of high-quality nano-materials with unique properties and enhanced performance. Most of these advanced techniques can yield ton-sized quantities or higher on a monthly basis, and enable to work collaboratively with customers to custom-manufacture nano-structured materials for specific needs and applications. The following techniques are used to manufacture the various nano-structured materials: The utilisation of the various aforementioned advanced processing techniques makes it possible to provide our customers with a wide variety of low-cost, high-quality, and large-quantity nano-structured materials such as: Carbon Nanotubes: single-walled, multi-walled, functionalised, dispersible carbon nanotubes. Carbon Nano-fibres: carbon nano-fibres and graphitised carbon nano-fibres. Elemental Nanoparticles: crystalline metals, amorphous metals, graphite, diamond, silicon, boron and other solids. Advanced Ceramic Nanoparticles: carbides, nitrides and borides. Oxide Nanoparticles: single-metal, multi-metal, rare earths, hydroxides, carbonates, sulfates, minerals and clays. Composite Nanoparticles: alloyed, doped, shelled and cored metals and oxides. Surface-Modifications: on oxides and their composites. High Surface Area Materials: graphite mates, sieves and holed beads. Amorphous Metallic Alloys: bulk, ribbons and powders. Catalytic Chemical Vapour Deposition: carbon nanotubes (CNTs) such as tangled CNTs, short dispersible CNTs, aligned CNTs, functionalised CNTs. A wide variety of inner diameters, outer diameters, lengths, functionalisations and purities are possible. Coatings-Modifications: a layer of hydrophilic PVP or hydrophobic oleic acid can improve dispersibility and compatibility, depending on application. Chemical Precipitation-Co-precipitation: single-metal oxides, multi-metal oxides and rare earth oxides. Hydrothermal Method: oxides with an average particle size of 20-80 nm and larger, up to 300-500 nm. Explosion: diamond nano-powders, with an average particle size of 3-15 nm. Electro-Explosion: metals and alloys, with an average particle size of 60-100 nm. Gas Jetting: brittle powders, from tens to hundreds of nanometers in average particle size. Laser Induced Chemical Vapor Deposition: Si, SiC and oxides, with average particle sizes around 10 nm, 50 nm and 100 nm, free from aggregation. Low Temperature Physical Method: brittle powders with no contamination, with micron and sub-micron average particle sizes. Mechanical Milling-Alloying: amorphous materials in powder form. Mechanical Milling: a flexible technique that can make brittle powders (average particle size down to 20 nm), can break down aggregated nano-powders and tangled carbon nanotubes, and can agglomerate nano-structured metals, alloys, oxides and carbides. Melt Solidification: amorphous materials in bulk form. Micro-emulsions: oxides and compounds with precise control of small (5-10 nm) average particle size. Sol-Gel: narrow particle size range and aggregated nano-powders. Plasma Enhanced Chemical Vapour Deposition: metals (average particle size of 25 nm, 60 nm, 80 nm and 120 nm) and silicon, carbides, borides and nitrides (average particle size of 5 nm, 10 nm, 30 nm, 60 nm, 200 nm, 300 nm and 500 nm), with a purity of 99% or 99.9%. Plasma Physical Vapor Deposition: vapor temperature less than 3,000 K, resulting in an average particle size of 90-150 nm and purities of 3N, 4N, 5N or higher. Nanoparticles can be solid elements, metal oxides, carbides, nitrides and more, with a special focus on nanoparticles with superior electronic properties. Wet Chemistry: metallic nano-powders (W, Mo, Ta, etc.), oxides and carbides. High-pressure wet chemistry is also possible for specific phases. These advanced processing technologies enable NanoAmor to achieve controllable products parameters such as components, composition, particle size, size distribution, morphology, surface area and purity. Some of our techniques can perform surface coating treatments, customisable to our customers' requests. Most of these techniques can yield ton-sized quantities or higher on a monthly basis, with reproducible inter-batch quality. For larger orders, we can test more detailed product information than what is usually provided.

Silica-based aerogel

Silica-based aerogel

Aerogel, known as the "world's best insulating solid material," is used to enhance the thermal performance of energy-saving materials and sustainable products for buildings, on- and off-shore industrial infrastructure and consumer products, as well as acting as a high performance additive to coatings and personal care offerings.

Evonik non-drip paint, a fumed silica-based product sold under the name of AEROSIL®. It is used to control rheological features and also to improve the corrosion resistance of paints.

Gallium arsenide has been used in performance-category solar modules for years because of its high conversion efficiencies. The challenge has always been its high cost relative to other solar materials. The photonic effect of our nanowires and the low cost of Aerotaxy production of Solfilm™ minimises the cost by dramatically reducing the amount of gallium arsenide and other expensive materials required to generate electricity. The gallium arsenide nanowires in Solfilm™ consist of only a small number of atoms, but are fully-functioning solar cells. the company produces gallium arsenide nanowires through an economical, high-throughput process called Aerotaxy® invented by company founder and Lund University professor Lars Samuelson. Nanowires and nanotubes are typically produced through an epitaxial process, i.e. slowly grown as crystals in low pressure/high temperature environments on silicon or sapphire substrates. Because of the inherent physical limits of the epitaxial process, nanoparticles often need to be grown in place or harvested and sorted in batch processes that can be both time-consuming and expensive. Aerotaxy® creates nanomaterials by suspending active materials in gases intermingled in precisely controlled environment. The suspended materials bond to form larger, uniform structures: nanowires are literally grown in space. Aerotaxy™ generates nanowires within milliseconds and can produce them on a continuous basis at comparatively low temperatures.