Reactive nanoparticles suspended in a silicon liquid medium that forms inorganic glass like coating on ferrous materials after curing. Used as anticorrosion and aberration resistant coating for pipe, rods, pumps and other equipments.
Ecosphere Technologies develops advanced water recycling technologies and expertise to increase energy production, reduce well completion costs and protect the environment. Its Ecosphere Ozonix Reactor Technology is a patented, advanced oxidation process that combines ozone generation, hydrodynamic cavitation, acoustic cavitation and electro-chemical decomposition in a reaction vessel to cost effectively treat wastewaters using nanoscale cavitation bubbles.
Provides expertise and solutions in the main areas of materials (incl. nanofiltration membranes and CNT based composites), catalysis (incl. nanostructured metallomacrocycle carbons) and catalytic systems, electrochemistry, membranes and sensors focused in the energy, petrochemicals, environmental monitoring and remediation, defense and the aerospace industries.
Manufactures ferrofluids, a stable colloidal suspension of magnetic nanoparticles in a liquid carrier. The particles, which have an average size of about 10 nm, are coated with a stabilizing dispersing agent (surfactant) which prevents particle agglomeration even when a strong magnetic field gradient is applied to the ferrofluid.
The Hosokawa Nano Particle Technology Center in Summit, New Jersey, is a newly established operation dedicated to the development, manufacture and commercialization of nano-particles and composite materials. The US operation works in close concert with Hosokawa's Nano Technology Centers in Japan to bring Americas based customers the latest Mechano Chemical Bonding (MCB) Technology.
Pioneered and continues to specialize in the design, manufacture, and application of Nanostructured® Chemical Tools derived from a class of chemicals known as Polyhedral Oligomeric Sil sesquioxanes (POSS®).
Design and development of advanced ceramic composite materials, coatings and thermal-structural components, including nanoengineered materials, produced by chemical vapor infiltration (CVI) and chemical vapor deposition (CVD).
Industrial Hard Carbon thin film coatings are characterized by extreme hardness, lubricity, high wear resistance, high corrosion resistance and a number of other useful qualities. The films are deposited by a proprietary plasma-assisted chemical vapor deposition process. Far different from the diamond-like and carbide thin films familiar to many in the coating industry, IHC films are created from layers of nano-crystalline diamond and nano-crystalline silicon carbide in an amorphous matrix of both elements.