The present disclosure is drawn to covers for electronic devices, methods of making the covers, and electronic devices. In one example, described herein is a cover for an electronic device comprising: a substrate comprising a metal; insert molded plastic on at least one surface of the substrate; a passivation layer or a micro-arc oxidation layer applied on at least one surface of the substrate; a coating composition on the passivation layer or the micro-arc oxidation layer; an outmoid decoration layer on the mating composition; a chamfered edge on the substrate, wherein the chamfered edge cuts through the outmoid decoration layer, the coating composition, the passivation layer or the micro-arc oxidation layer, and partially through the substrate; and wherein the chamfered edge comprises; a transparent passivation layer, then an optional sealing layer, and then a transparent or color electrophoretic deposition coating layer.

The present disclosure is drawn to covers for electronic devices, methods of making the covers, and electronic devices. In one example, described herein is a cover for an electronic device comprising: a substrate comprising a metal; insert molded plastic on at least one surface of the substrate; a passivation layer or a micro-arc oxidation layer applied on at least one surface of the substrate; a coating composition on the passivation layer or the micro-arc oxidation layer; an outmoid decoration layer on the mating composition; a chamfered edge on the substrate, wherein the chamfered edge cuts through the outmoid decoration layer, the coating composition, the passivation layer or the micro-arc oxidation layer, and partially through the substrate; and wherein the chamfered edge comprises; a transparent passivation layer, then an optional sealing layer, and then a transparent or color electrophoretic deposition coating layer.

A method to produce a light-emitting device package includes mounting junctions on pads of a metalized substrate, where the junctions are at least partially electrically insulated from each other, and forming wavelength converters, where each wavelength converter is located over a different junction and separated by a gap from neighboring wavelength converters.

A method to produce a light-emitting device package includes mounting junctions on pads of a metalized substrate, where the junctions are at least partially electrically insulated from each other, and forming wavelength converters, where each wavelength converter is located over a different junction and separated by a gap from neighboring wavelength converters.

Graphene is formed with a practically uniform thickness on an uneven object. The object is immersed in a graphene oxide solution, and then taken out of the solution and dried; alternatively, the object and an electrode are immersed therein and voltage is applied between the electrode and the object used as an anode. Graphene oxide is negatively charged, and thus is drawn to and deposited on a surface of the object, with a practically uniform thickness. After that, the object is heated in vacuum or a reducing atmosphere, so that the graphene oxide is reduced to be graphene. In this manner, a graphene layer with a practically uniform thickness can be formed even on a surface of the uneven object.

Graphene is formed with a practically uniform thickness on an uneven object. The object is immersed in a graphene oxide solution, and then taken out of the solution and dried; alternatively, the object and an electrode are immersed therein and voltage is applied between the electrode and the object used as an anode. Graphene oxide is negatively charged, and thus is drawn to and deposited on a surface of the object, with a practically uniform thickness. After that, the object is heated in vacuum or a reducing atmosphere, so that the graphene oxide is reduced to be graphene. In this manner, a graphene layer with a practically uniform thickness can be formed even on a surface of the uneven object.

A coated metal alloy substrate for an electronic device, a process for producing a coated metal alloy substrate for an electronic device and a housing for an electronic device, comprising a coated metal alloy substrate wherein the coated metal alloy CA substrate comprises at least one chamfered edge (1) and comprises: a passivation layer (2) deposited on the at least one chamfered edge (1); an electrophoretic deposition layer (3) deposited on the passivation layer (2); and a hydrophobic layer (4) deposited on the electrophoretic deposition layer (3).

A coated metal alloy substrate for an electronic device, a process for producing a coated metal alloy substrate for an electronic device and a housing for an electronic device, comprising a coated metal alloy substrate wherein the coated metal alloy CA substrate comprises at least one chamfered edge (1) and comprises: a passivation layer (2) deposited on the at least one chamfered edge (1); an electrophoretic deposition layer (3) deposited on the passivation layer (2); and a hydrophobic layer (4) deposited on the electrophoretic deposition layer (3).

Provided is a method of manufacturing an electrolyte for dye-sensitized solar cells, the method including: preparing a hydrogel membrane; immersing the hydrogel membrane in an electrolyzing solution containing iodine or iodide such that the hydrogel membrane is impregnated with iodide ions; and drying the hydrogel membrane.

Provided is a method of manufacturing an electrolyte for dye-sensitized solar cells, the method including: preparing a hydrogel membrane; immersing the hydrogel membrane in an electrolyzing solution containing iodine or iodide such that the hydrogel membrane is impregnated with iodide ions; and drying the hydrogel membrane.