Semiconductor packages may include different portions associated one or more electronic components of the semiconductor package where electromagnetic (for example, radio-frequency, RF) shielding at predetermined frequencies ranges may be needed. Accordingly, in an embodiment, compartmental shielding can be used in the areas between the electronic components on the semiconductor package to provide RF shielding to the electronic components on the semiconductor package or to other electronic components in proximity to the electronic components on the semiconductor package. Further, in another embodiment, conformal coating shielding can be used to provide RF shielding to provide RF shielding to the electronic components on the semiconductor package or to other electronic components in proximity to the electronic components on the semiconductor package.

An exemplary embodiment of the present invention relates to a conductive structure body that comprises a darkening pattern layer having AlOxNy, and a method for manufacturing the same. The conductive structure body according to the exemplary embodiment of the present invention may prevent reflection by a conductive pattern layer without affecting conductivity of the conductive pattern layer, and improve a concealing property of the conductive pattern layer by improving absorbance. Accordingly, a display panel having improved visibility may be developed by using the conductive structure body according to the exemplary embodiment of the present invention.

A module includes a printed circuit board (PCB) having a substrate, component pads on a top surface of the substrate, and contact pads formed on a bottom surface of the substrate. The module further includes a mold compound disposed over the PCB; an external shield disposed over a top surface of the mold compound and on side surfaces of the mold compound and the PCB, where the external shield is configured to provide shielding of at least one component connected to at least one component pad from electromagnetic radiation; and a back-spill barrier formed on the bottom of the substrate. The back-spill barrier surrounds the contact pads, and is configured to prevent the external shield from making contact with the contact pads.

The present invention discloses a method for manufacturing a printed circuit board having an ultra-thin metal layer. The method discharges alkaline aliphatic amine gas and the nitrogen bubbled in the cupric sulfate solution via capacitive coupling in a vacuum, to generate low temperature plasma. The polyimide film and the epoxy resin board coated with fiberglass cloth are etched and the surface is treated to graft active groups, so as to increase the surface roughness and chemical activity. Subsequently, sputtering copper plating or chemical copper plating is directly conducted. The electroplating is conducted to thicken the copper film to a required thickness. The method of the invention not only does not need adhesive (adhesive free), but also has a high peeling strength. It can be used for the preparation of the flexible PCB, the rigid PCB, the multi-layer PCB, and rigid-flex PCB, having an ultra-thin metal layer.

A flexible printed circuit board includes a substrate, a circuit pattern formed on the substrate, and a protective coating layer formed on the substrate by applying and curing a coating solution to cover and protect the circuit pattern. A method for manufacturing forming a circuit pattern on a substrate and forming a protective coating layer for covering and protecting the circuit pattern by applying a coating solution on the substrate. The circuit pattern may be securely attached to the substrate, and damage and deformation of the circuit pattern due to repeated bending or warping of the substrate may be prevented, ultimately improving operational reliability.

A wiring board including a first resin layer, wiring patterns arranged on at least one surface of the first resin layer, and a second resin layer disposed between the wiring patterns and on the wiring patterns, in which, in a cross section along a thickness direction, an interface roughness Rz1 of an interface between the first resin layer and the second resin layer is larger than an interface roughness Rz2 of an interface between the first resin layer and the wiring pattern; and applications thereof are provided.

A ceramic substrate manufacturing method and a ceramic substrate manufactured thereby, may include a seed layer, a brazing filler layer, and a metal foil that are laminated on a ceramic substrate and that are brazed such that the metal foil is firmly bonded to the ceramic substrate by a brazing joint layer. Such methods and devices may substantially improve the adhesion of the metal foil and the ceramic substrate.

A through wiring substrate comprises a substrate having a pair of principal surfaces and a through hole penetrating between the pair of principal surfaces, the pair of principal surfaces and an inner surface of the through hole being electrically insulative; a through electrode provided on the inner surface of the through hole; a first wiring layer provided on one of the principal surfaces and connected to the through electrode; a second wiring layer provided on the other of the principal surfaces and connected to the through electrode; an underlying metal layer provided between the one of the principal surfaces and the first wiring layer; and catalyst metal particles existing between the underlying metal layer and the first wiring layer and between the through electrode and the inner surface of the through hole.

A circuit board comprising a substrate and a circuit trace. The substrate includes a surface etched via ion milling over a circuit area such that the surface has an increased roughness. The circuit trace forms portions of an electronic circuit and may be created from a thin conductive film deposited on the surface within the circuit area. The circuit trace adheres more strongly to the roughened substrate surface, which prevents the circuit trace from peeling or becoming delaminated from the substrate surface.

A chip part includes a substrate, a first electrode and a second electrode which are formed apart from each other on the substrate and a circuit network which is formed between the first electrode and the second electrode. The circuit network includes a first passive element including a first conductive member embedded in a first trench formed in the substrate and a second passive element including a second conductive member formed on the substrate outside the first trench.