An object of the present invention is to provide a laminate having high scratch resistance, weather fastness and solvent resistance, and capable of achieving both light-transmitting properties and metallic luster. The laminate includes a metal foil having a plurality of through-holes that pass through in a thickness direction; and a protective layer provided on at least one surface of the metal foil, in which the protective layer contains a metal oxide, the metal foil has an average opening diameter of the through-holes of 0.1 μm to 100 μm and an average opening ratio, which is determined by the through-holes, of 0.1% to 90%, and the protective layer has a light transmittance of 10% or more.

Disclosed are polymers, methods of making polymers, and compositions, focused on cross-linking heterocycles comprising a moiety of Formula I with thiols and thiolates.

Disclosed are polymers, methods of making polymers, and compositions, focused on cross-linking heterocycles comprising a moiety of Formula I with thiols and thiolates.

A method for coating a substrate includes forming a conversion coat layer, depositing a protective coat onto the protective coat onto the conversion coat, and depositing a corrosion resistant top coat onto the protective coat. The conversion coat layer is formed by applying a conversion coat onto the substrate. The protective coat is deposited using a first atomic layer deposition. The corrosion resistant top coat is deposited using a second atomic layer deposition. The conversion coat layer has a volatizing temperature, and the first atomic layer deposition is performed at a deposition temperature that is no greater than 1.3 times the volatizing temperature of the conversation coat layer, calculated in Kelvin.

A doping method using an electric field includes stacking a sacrificial layer on a doped layer, disposing a doping material on the sacrificial layer, disposing electrodes on the doping material and the doped layer, respectively, and doping the doping material into the doped layer through oxidation, diffusion, and reduction of the doping material by the electric field.

Convenient anodizing is provided through a pen form factor anodizing tool having a reservoir for holding anodizing fluid and an electrical cable connection communicating electrical power to a tip dispensing anodizing fluid from the reservoir at a anodizing voltage from electrical power through the electrical cable connection.

A method of forming a corrosion-resistant ceramic coating on a metallic substrate, the method comprising providing a passivation layer on a surface of the metallic substrate by electrochemical passivation of the metallic substrate under a first electrical current and using a first electrically conducting solution; and providing the corrosion-resistant ceramic coating on an outermost surface of the metallic substrate, the outermost surface in use adapted to be exposed to a corrosive environment, by plasma electrolytic oxidation of the metallic substrate with the passivation layer, in a second electrically conducting solution and under a second electrical current having a discharge voltage. The first and the second electrically conducting solutions comprise a tetrafluoroborate compound.

A substrate (1, 10) for electrical circuits, comprising at least one metal layer (2,3, 14) and a paper ceramic layer (11), which is joined face to face with the at least one metal layer (2,3, 14) and has a top side and bottom side (11a, 11b), wherein the paper ceramic layer (11) has a large number of cavities in the form of pores. Especially advantageously, the at least one metal layer (2, 3, 14) is connected to the paper ceramic layer (11) by means of at least one glue layer (6, 6a, 6b), which is produced by applying at least one glue (6a, 6a, 6b, 6b) to the metal layer (2,3, 14) and/or to the paper ceramic layer (11), wherein the cavities in the form of pores in the paper ceramic layer (11) are filled at least at the surface by means of the applied glue (6a, 6a, 6b,6b).

A structure includes a metal layer and a plurality of interconnected unit cells forming a lattice contained at least partly within the metal layer, including at least a first unit cell formed of first interconnected graphene tubes, and a second unit cell formed of second interconnected graphene tubes, wherein the metal layer protrudes through holes within the lattice.

A structure includes a metal layer and a plurality of interconnected unit cells forming a lattice contained at least partly within the metal layer, including at least a first unit cell formed of first interconnected graphene tubes, and a second unit cell formed of second interconnected graphene tubes, wherein the metal layer protrudes through holes within the lattice.