The present disclosure relates to blended thermoplastic compositions comprising: a) from about 20 wt % to about 80 wt % of a polycarbonate polymer component; b) from about 5 wt % to about 30 wt % of a polycarbonate-polysiloxane copolymer component; c) from about 1 wt % to about 20 wt % of a laser direct structuring additive component; and d) from about 0.02 wt % to about 5 wt % of a metal component; wherein the combined weight percent value of all components does not exceed about 100 wt %; and wherein all weight percent values are based on the total weight of the composition.

A method for metalizing a polymer substrate and a polymer article prepared thereof. First a polymer substrate having a base polymer and at least one metal compound dispersed in the base polymer is provided. A surface of the polymer substrate is then irradiated with an energy beam such that a water contact angle of the surface of the polymer substrate is at least 120. And then the surface of the polymer substrate is subjected to chemical plating.

A nanoimprint lithography method to remove uncured pretreatment composition from an imprinted nanoimprint lithography substrate. The method includes disposing a pretreatment composition on a nanoimprint lithography substrate to form a pretreatment coating and disposing discrete portions of imprint resist on the pretreatment coating, each discrete portion of the imprint resist covering a target area of the nanoimprint lithography substrate. A composite polymerizable coating is formed on the nanoimprint lithography substrate as each discrete portion of the imprint resist spreads beyond its target area, and the composite polymerizable coating is contacted with a nanoimprint lithography template. The composite polymerizable coating is polymerized to yield a composite polymeric layer and an uncured portion of the pretreatment coating on the nanoimprint lithography substrate, and the uncured portion of the pretreatment coating is removed from the nanoimprint lithography substrate.

A reactor block to extract hydrogen from water includes a plurality of reactor plates bonded to one another and a plurality of channels formed on at least one side of each reactor plate. Each channel is coupled to a first opening and a second opening disposed on opposite first and second edges of the reactor plate, and a radioactive coating is applied to each channel. The first opening is configured to receive gasified water and the second opening is configured to eject hydrogen generated by radiolysis of at least a portion of the gasified water as the gasified water is passed through the channel coupled to the second opening.

A reactor block to extract hydrogen from water includes a plurality of reactor plates bonded to one another and a plurality of channels formed on at least one side of each reactor plate. Each channel is coupled to a first opening and a second opening disposed on opposite first and second edges of the reactor plate, and a radioactive coating is applied to each channel. The first opening is configured to receive gasified water and the second opening is configured to eject hydrogen generated by radiolysis of at least a portion of the gasified water as the gasified water is passed through the channel coupled to the second opening.

The inventions disclosed by this application are for a cladding apparatus, a cladding head, and a method of cladding a relatively planar solid object such as a boiler waterwall. Cladding of non-horizontal surfaces is complicated by the effects of gravity as melted clad material trends to runoff the surface before the cladding material bonds to the appropriate location. The disclosed inventions overcome these limitations by controlling the relative angle of application by either rotating the workpiece or the cladding head through a pre-programmed sequence. Also presented in a compact design for a laser cladding head that facilitates such cladding by minimizing movement of the laser fiber and improves cladding speed over irregular shaped objects.

The presently-disclosed subject matter includes methods for making a copper ink. In some embodiments the methods comprise forming an aqueous solution that includes copper and adding an amount of a surfactant to the aqueous solution to thereby produce a copper ink that includes a dispersion of copper nanoparticles. In some embodiments the methods further include adding an amount of a reducing agent to the aqueous solution. In some instances the copper inks are formed from copper salts, and in some embodiments the copper inks do not include oxides of copper. The presently-disclosed subject matter also includes copper inks formed by the presently-disclosed methods as well as methods of forming a copper film from a copper ink.

The present application relates to a method of preparing a metal pattern having a 3D structure, a metal pattern laminate, and use of the metal pattern laminate. According to the method of preparing a metal pattern, the metal pattern having a 3D structure can be effectively formed on a receptor. Especially, the metal pattern having a 3D structure can also be effectively and rapidly transferred to a surface of the receptor, such as, a flexible substrate, to which the metal pattern is not easily transferred. The metal pattern laminate prepared using the method can, for example, be usefully used for metal layers of flexible electronic devices or metal interconnection lines.

A method for improving the heat sealability of a packaging material and a method for manufacturing a heat-sealed container or package are described. The material can be polymer-coated packaging paper or cardboard, or a polymeric packaging film. The material includes a polymer layer that contains polyester, particularly polylactide, the heat sealability of which is improved by ultraviolet radiation. Polylactide is useful as such or when blended, for example, with other biodegradable polyester. The containers and packages thus manufactured include disposable drinking cups and cardboard carton and box packages.

A reactor block to extract hydrogen from water includes a first opening configured to receive gasified water, a second opening, and a reactor plate. A channel is formed in the reactor plate and disposed in a fluid path between the first opening and the second opening and a radioactive coating is applied to the channel. The second opening is configured to eject hydrogen generated by radiolysis of at least a portion of the gasified water received at the first opening and passed through the channel to the second opening.