A method of producing an optoelectronic semiconductor component includes providing a semiconductor body; applying a photoconductive layer on a radiation exit surface of the semiconductor body, wherein the semiconductor body emits electromagnetic radiation during operation; exposing at least one sub-region of the photoconductive layer with electromagnetic radiation generated by the semiconductor body; and depositing a conversion layer on the sub-region of the photoconductive layer by an electrophoresis process.

Manufacturing steps for manufacturing a hand tool include a step of preparing a base part which has a handle end and a head end; a step of molding: placing the base part in a molding device and coating plastic to the whole base part by way of plastic injection molding to form the base part into a semi-product which has a handle portion and a head portion, an installation hole defined through the head portion; a step of coating: electro-coating a material to outer surface of the plastic of the semi-product, and a step of assembly: assembling a ratchet driving unit in the installation hole by using fixing members so as to obtain a final product.

Manufacturing steps for manufacturing a hand tool include a step of preparing a base part which has a handle end and a head end; a step of molding: placing the base part in a molding device and coating plastic to the whole base part by way of plastic injection molding to form the base part into a semi-product which has a handle portion and a head portion, an installation hole defined through the head portion; a step of coating: electro-coating a material to outer surface of the plastic of the semi-product, and a step of assembly: assembling a ratchet driving unit in the installation hole by using fixing members so as to obtain a final product.

Functionalized membranes for use in applications, such as electrodeionization, can be prepared simply and efficiently by contacting a conductive carbon nanotube and polymer membrane with a solution containing at least one electrochemically active and functional compound under conditions suitable for electrochemically depositing the electrochemically active and function compound on a surface of the membrane.

Functionalized membranes for use in applications, such as electrodeionization, can be prepared simply and efficiently by contacting a conductive carbon nanotube and polymer membrane with a solution containing at least one electrochemically active and functional compound under conditions suitable for electrochemically depositing the electrochemically active and function compound on a surface of the membrane.

According to one example, preparing a substrate for an electronic device can include forming a deposition layer on a magnesium alloy substrate, anodizing the magnesium alloy substrate, and forming an electrophoretic deposition layer on the anodized magnesium alloy substrate.

Embodiments of the present application provide a color filter substrate, a method for manufacturing the color filter substrate, a display panel and a display device. The color filter substrate includes: a substrate; a color filter layer disposed on the substrate, the color filter layer including a plurality of sub color filter layers spaced apart from each other; a process electrode layer disposed on the substrate and within a gap between any two adjacent sub color filter layers; and a black matrix disposed within the gap between the any two adjacent sub color filter layers and on the corresponding process electrode layer, and connected with the adjacent sub color filter layer without any overlap therebetween.

A method for manufacturing an electrode for a lithium-based battery by electrophoretic deposition is provided. The method includes: mixing particles with graphene oxide and a binder in a solution, the particles including a material selected from silicon, silicon oxide, silicon alloys, tin, tin oxide, sulfur, lithium manganese oxide, lithium cobalt oxide, lithium nickel oxide, lithium nickel manganese oxide, and lithium nickel manganese cobalt oxide. The method further includes applying a potential between a current collector and a counter electrode immersed in the solution to deposit a coating of a combination of the particles, at least partially reduced graphene oxide, and binder onto the current collector. The method still further includes drying the coated current collector.

A method for manufacturing an electrode for a lithium-based battery by electrophoretic deposition is provided. The method includes: mixing particles with graphene oxide and a binder in a solution, the particles including a material selected from silicon, silicon oxide, silicon alloys, tin, tin oxide, sulfur, lithium manganese oxide, lithium cobalt oxide, lithium nickel oxide, lithium nickel manganese oxide, and lithium nickel manganese cobalt oxide. The method further includes applying a potential between a current collector and a counter electrode immersed in the solution to deposit a coating of a combination of the particles, at least partially reduced graphene oxide, and binder onto the current collector. The method still further includes drying the coated current collector.

A method of manufacturing a color filter is provided. The method includes: forming at least black matrix electrodes, first electrodes, second electrodes and third electrodes insulated from each other on a base substrate; and depositing at least a black matrix layer, a first color filter pattern, a second color filter pattern and a third color filter patter on the base substrate using an electrophoretic deposition process respectively by means of the black matrix electrodes, the first electrodes, the second electrodes and the third electrodes. A color filter and a display device are also provided. The described solution provides a process which is simple, convenient to operate, ease of control, and allows fast film formation.