The present disclosure provides electronic device and methods of manufacturing the electronic devices. In some embodiments, the electronic device includes an outer housing at least partially forming an exterior of the electronic device, a trench including at least one valley and at least one peak, a first conductive member, and a coating layer laminated on the outer housing and disposed on the first conductive member. Each of the at least one valley is concave with respect to a surface of the outer housing. Each of the at least one peak is convex with respect to the surface of the outer housing and has a partially removed end. The trench is plated with the first conductive member.

The invention relates to nickel-coated hexagonal boron nitride nanosheet composite powder, its preparation and high-performance composite ceramic cutting tool material. The composite powder has a core-shell structure with BNNS as the core and Ni as the shell. The self-lubricating ceramic cutting tool material is prepared by wet ball milling mixing and vacuum hot-pressing sintering with a phase alumina as the matrix, tungsten-titanium carbide as the reinforcing phase, nickel-coated hexagonal boron nitride nanosheet composite powder as the solid lubricant and magnesium oxide and yttrium oxide as the sintering aids. The invention also provides preparation methods of the nickel-coated hexagonal boron nitride nanosheet composite powder and the self-lubricating ceramic cutting tool material.

A circuit board has a dielectric core, a foil top surface, and a thin foil bottom surface with a foil backing of sufficient thickness to absorb heat from a laser drilling operation to prevent the penetration of the thin foil bottom surface during laser drilling. A sequence of steps including a laser drilling step, removing the foil backing step, electroless plating step, patterned resist step, electroplating step, resist strip step, tin plate step, and copper etch step are performed, which provide dot vias of fine linewidth and resolution.

A decorative work piece or component, such as a decorative automotive trim component, and method for plating a work piece is provided. An electroless layer of material is applied to the work piece using an electroless plating process. A barrier in electrical conductivity is provided on the work piece to divide the work piece into a first segment and a second segment which are substantially electrically insulated from one another, prior to electroplating the work piece. A plurality of methods are disclosed for dividing the work piece into the first and second segments. The component includes different surface finishes on each of the electrically isolated segments, with the finishes having different appearance, gloss level, color, and/or distinction of image as a result of electroplating and without post-electroplating mechanical alteration and assembly.

Provided is an alloy material including a metal oxide thin layer that can be formed using a simple method at low cost and can further suppress volatilization of Cr, which causes deterioration of a fuel cell, compared with a case where conventional expensive materials are used. Disclosed is a manufacturing method for an alloy material including a coating treatment step for coating a substrate made of a Fe—Cr based alloy with Co, and an oxidation treatment step for performing oxidation treatment on the substrate in a moisture-containing atmosphere after the coating treatment step.

Described herein are apparatus and methods for the continuous application of nanolaminated materials by electrodeposition.

A metal resin composite includes a metal substrate, a metal layer formed on a surface of the metal substrate, and a resin layer formed on the metal layer. A plurality of microcracks are formed at a surface of the metal layer.

A method for electroless deposition of aluminum or an aluminum alloy on a substrate surface. The method includes activating the surface of the substrate to be coated by applying a coating of a catalyst metal; preparing a mixture of urea ((NH.sub.2CONH.sub.2) and anhydrous aluminum chloride (AlCl.sub.3) wherein a molar ratio of AlCl.sub.3:(NH.sub.2CONH.sub.2 is greater than 1:1 to obtain a Lewis acid room temperature ionic liquid (RTIL) optionally containing an alloy metal salt; dissolving a hydride reducing agent in an aprotic anhydrous solvent to obtain a hydride solution; mixing the hydride solution and the AlCl.sub.3:(NH.sub.2CONH.sub.2 RTIL to obtain an electroless Al solution; exposing the activated surface of the substrate to the electroless Al solution; and removing the electroless Al solution from the substrate surface; wherein upon exposure of the activated substrate surface to the electroless Al solution, an Al or Al alloy coating is obtained on the activated substrate surface.

A method for producing metal patterns, which includes depositing a temporary protection on a substrate surface corresponding to the negative of the patterns to be produced; depositing at least one metal on the areas corresponding to the patterns to be produced; and eliminating the temporary protection at least partly during and/or after, or at least partly during and/or after the deposition step. The method can produce decorative objects or functional objects such as printed circuits, integrated circuits, RFID chips, and electronic reader-readable encoding pictograms. A set of consumables used to implement the method is also disclosed.

A piston ring for an engine may include a piston ring body. The piston ring body may include a working surface, a lower surface, an upper surface, and an inner surface. An area of the working surface and/or the lower surface which is close to an outer circumferential lower edge of the piston ring body is not provided with a nitride layer, the outer circumferential lower edge is formed with a chamfer, the chamfer does not have a nitride layer, and an additional area of the piston ring has a nitride layer.