A method is disclosed for forming nanoscale coatings on a solid substrate surface. In certain embodiments, the method includes the following steps: contacting a substrate with a first liquid organic solvent; adding a liquid agent to the first liquid organic solvent to form a liquid agent film on a surface of the substrate; and adding the nanocoating precursor in the first liquid organic solvent to react the nanocoating precursor with the liquid agent to form the nanocoating on the surface of the substrate.

A method is disclosed for forming nanoscale coatings on a solid substrate surface. In certain embodiments, the method includes the following steps: contacting a substrate with a first liquid organic solvent; adding a liquid agent to the first liquid organic solvent to form a liquid agent film on a surface of the substrate; and adding the nanocoating precursor in the first liquid organic solvent to react the nanocoating precursor with the liquid agent to form the nanocoating on the surface of the substrate.

Particles with suitable properties may be generated using systems and methods provided herein. The particles may include carbon particles.

A manufacturing process for an anti-dust and easily dispersible carbon black pigment is disclosed herein. The pigment is convenient to handle and does not generate potentially hazardous airborne particles during transportationor duringany suitable processing conditions employed in end applications in the relevant industry including cosmetics, paint or ink.

A manufacturing process for an anti-dust and easily dispersible carbon black pigment is disclosed herein. The pigment is convenient to handle and does not generate potentially hazardous airborne particles during transportationor duringany suitable processing conditions employed in end applications in the relevant industry including cosmetics, paint or ink.

Carbon blacks such as reinforcing-grade carbon blacks with high structure are described. The carbon black can have the following properties: a statistical thickness surface area (STSA) ranging from 80 m.sup.2/g to 150 m.sup.2/g, an oil absorption number (OAN) of at least 180 mL/100 g, and a crushed oil absorption number (COAN) of at least 110 mL/100 g. Rubber compounds which incorporate the carbon black also are described.

Carbon blacks such as reinforcing-grade carbon blacks with high structure are described. The carbon black can have the following properties: a statistical thickness surface area (STSA) ranging from 80 m.sup.2/g to 150 m.sup.2/g, an oil absorption number (OAN) of at least 180 mL/100 g, and a crushed oil absorption number (COAN) of at least 110 mL/100 g. Rubber compounds which incorporate the carbon black also are described.

The present invention relates to a method for oxidizing a carbon black which can prevent or alleviate change in the surface oxidation degree of the carbon black by a residual ozone after surface oxidation reforming, and a method for preparing the carbon black by comprising it in a single continuous process.

An ink mixture is manufactured by mixing carbon, graphite, and solvents in a mixing system which may include a Cowles disperser. The conductive portions (e.g. carbon, graphite) are evenly and universally dispersed, because an even dispersal means the conductivity of the resulting conductive strip (electrode) will be even, consistent, and reliable. The various embodiments of the ink mixture comprise a blend of different conductive pigments, including but not limited to carbon black and graphite. These embodiments must be grinded until below 6.5 Microns in particle size.

A composite polymer composition comprising partially crystallized carbon black. The composition exhibits superior thermal transfer properties in plastic formulations. The polymer precursor exhibits excellent rheology when compared to similar compositions comprising traditional carbon blacks. The composite polymers provide for higher loading of more thermally conductive carbon blacks in a variety of composite polymer compositions.