A circuit board includes at least two circuit board units. Each of the circuit board units includes a baseboard having a conductive hole filled with an electrical conductor, and a cover layer arranged on the baseboard and defining at least one trench and at least one opening. The at least one opening exposes out the electrical conductor. A circuit pattern is embedded in the at least one trench and includes a connecting portion. The connecting portion is embedded in the opening and is electrically coupled to the electrical conductor. The at least two circuit board units are stacked. Two sides of the at least one cover layer are respectively adhered to the corresponding baseboard. Two ends of the at least one connecting portion are respectively electrically coupled to the corresponding electrical conductor and electrically coupled the two adjacent circuit patterns.

The present subject matter relates to the method of manufacturing circuit having lamination layer using LDS (Laser Direct Structuring) to ease the application on surface structure for applied product of various electronic circuit and particularly, in which can form circuit structure of single-layer to multiple-layer on the surface of injection-molded substrate in the shape of plane or curved surface, metal product, glasses, ceramic, rubber or other material.

A method for producing a laser-structurable component, wherein an extruded single- or multilayer molded part with at least one laser-structurable layer that forms an exposed surface of the molded part is applied onto the surface of a non-laser-structurable support element. Alternatively, the at least one laser-structurable layer may be back-molded with a non-laser-structurable thermoplastic support element so that at least one laser-structurable layer of the molded part forms at least one part of the surface of the laser-structurable component. The extruded single- or multilayer molded part is deep-drawn into the component. In the process, the laser-structurable layer of the molded part consists of a thermoplastic molding compound consisting of: (A) 30-99.9 wt. % of a thermoplastic consisting of polyamide; (B) 0.1-10 wt. % of an LDS additive; and (C) 0-60 wt. % of an additive material which is different from (A) and (B).

A packaged device may include electrical components such as integrated circuits that are mounted to a substrate such as a printed circuit substrate. Plastic may be molded to the printed circuit substrate over the integrated circuits. The molded plastic may include one or more shots of plastic and may include laser-sensitizable plastic material. Antenna structures may be supported by molded plastic such as molded plastic in a packaged device. The antenna structures may be formed from metal foil, flexible printed circuit substrate material with metal antenna traces, and metal traces that are formed on exposed surfaces of the plastic. The metal traces may be electroplated metal traces that are formed on regions of a laser-sensitizable plastic material that have been exposed to laser light. A package may have a protrusion that supports an antenna structure.

A circuit board is formed from a catalytic laminate having a resin rich surface with catalytic particles dispersed below a surface exclusion depth. Trace channels and apertures are formed into the catalytic laminate, electroless plated with a metal such as copper, filled with a conductive paste containing metallic particles, which are then melted to form traces. In a variation, multiple circuit board layers have channels formed into the surface below the exclusion depth, apertures formed, are electroless plated, and the channels and apertures filled with metal particles. Several such catalytic laminate layers are placed together and pressed together under elevated temperature until the catalytic laminate layers laminate together and metal particles form into traces for a multi-layer circuit board.

The invention relates to a thermoplastic composition comprising a thermoplastic polymer, a laser direct structuring (LDS) additive and a LDS synergist, wherein the composition comprises: (A) a thermoplastic polymer; (B) a LDS additive comprising a tin-based metal oxide; and (C) a metal salt of a phosphinic acid or a diphosphinic acid, or any mixtures thereof.

The present invention relates to a composition for forming a conductive pattern, which is able to form a fine conductive pattern onto a variety of polymer resin products or resin layers by a very simple process, a method for forming the conductive pattern using the same, and a resin structure having the conductive pattern. The composition for forming the conductive pattern, including a polymer resin; and a non-conductive metal compound containing a first metal and a second metal, in which the non-conductive metal compound has a three-dimensional structure containing a plurality of first layers that contains at least one metal of the first and second metals and has edge-shared octahedrons two-dimensionally connected to each other, and a second layer that contains a metal different from that of the first layer and is arranged between the neighboring first layers; and a metal core containing the first or second metal or an ion thereof is formed from the non-conductive metal compound by electromagnetic irradiation.

Graphene oxide is used as an insulation barrier layer for metal deposition. After patterning and modification, the chemical characteristics of graphene oxide are induced. It can be used as the catalyst for electroless plating in the metallization process, so that the metal is only deposited on the patterned area. It provides the advantages of improving reliability and yield. The metallization structure includes a substrate, a graphene oxide catalytic layer, and a metal layer. It may be widely applied to the metallization of the fine pitch metal of a semiconductor package as well as the fine pitch wires of a printed circuit board (PCB), touch panels, displays, fine electrodes of solar cells, and so on.

A pixel circuit, driving method thereof, organic light-emitting display panel and display apparatus, comprise driving transistor, first storage capacitor, collecting unit, writing unit and light-emitting unit; the collecting unit is used for collecting the threshold voltage of the driving transistor and storing the threshold voltage into the first storage capacitor, under the control of the first scan signal; the writing unit is used for storing the data voltage inputted from the input terminal for the data voltage under the control of the second scan signal; and the light-emitting unit is used for emitting lights, driven by the data voltage and a voltage inputted from the input terminal for the controllable low voltage, under the control of the light-emitting control signal. Thus, the organic light-emitting device is not affected by the threshold voltage shift of the driving transistor, which may enhance the image uniformity of the organic light-emitting display panel effectively.

A method for selectively metallizing a surface of a ceramic substrate, a ceramic product and use of the ceramic product are provided. The method comprises steps of: A) molding and sintering a ceramic composition to obtain the ceramic substrate, in which the ceramic composition comprises a ceramic powder and a functional powder dispersed in the ceramic powder; the ceramic powder is at least one selected from a group consisting of an oxide of E, a nitride of E, a oxynitride of E, and a carbide of E; E at least one selected from a group consisting of Li, Na, K, Rb, Cs, Be, Mg, Ca, Sr, Ba, B, Al, Ga, Si, Ge, P, As, Sc, Y, Zr, Hf, is and lanthanide elements; the functional powder is at least one selected from a group consisting of an oxide of M, a nitride of M, a oxynitride of M, a carbide of M, and a simple substance of M; and M is at least one selected from a group consisting of Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, Ta, W, Re, Os, Ir, Pt, Au, In, Sn, Sb, Pb, Bi, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu; B) radiating a predetermined region of the surface of the ceramic substrate using an energy beam to form a chemical plating active center on the predetermined region of the surface of the ceramic substrate; and C) performing chemical plating on the ceramic substrate formed with the chemical plating active center to form a metal layer on the predetermined region of the surface of the ceramic substrate.