Electrically conductive patterns formed on a substrate are provided with a reduced visibility. A region of a major surface of the substrate is selectively roughened to form a roughened pattern on the major surface of the substrate. Electrically conductive traces are directly formed on the roughened region and are conformal with the roughened pattern on the major surface of the substrate.

Configurable semiconductor packages and processes to attain a defined configuration are provided. A configurable semiconductor package includes a base semiconductor package including a semiconductor die mounted on a surface of a package substrate. An expansion package can be mechanically coupled to a mounting member. The expansion package includes a second package substrate and one or more second semiconductor dies that can be surface mounted to the second package substrate. The second package substrate include an array of interconnects that permit coupling (mechanically and/or electrically) the second semiconductor die(s) to the package substrate of the base semiconductor package. The mounting member can mechanically attach to the base semiconductor package, resulting in a package assembly that has the array of interconnects adjacent to another array of interconnects in the package substrate of the base semiconductor package. The expansion package can be coupled to the base semiconductor package via the interconnects, providing expanded functionality relative to the functionality of the base semiconductor package.

A display device includes a substrate having a flat portion, a first curved portion adjacent to a side of the flat portion, and a second curved portion adjacent to a corner of the flat portion and the first curved portion, and a display unit on the substrate, the display unit including a plurality of display pieces on the second curved portion of the substrate, the display pieces being spaced apart from each other, and extending from the corner of the flat portion to an edge of the second curved portion.

Described herein are molecular inks, methods for printing the molecular inks on flexible substrates, and methods for forming printed electronic elements, such as resistive heaters, force sensors, motion sensors, and devices that include these elements, such as force responsive conductive heaters. The methods include printing a molecular ink on a flexible substrate that is heated to 30? C. to 90? C. before and/or during the printing process and curing the substrate to produce a conductive pattern thereon. The molecular inks generally include a particle-fee metal-complex composition formulated from at least one metal complex and a solvent, and optionally, a conductive filler material, and/or surfactant.

The present invention provides a ceramic circuit board comprising: a ceramic substrate; and at least one of a recess and a through-hole formed in the ceramic substrate, wherein a conductive portion filled with a conductor is provided in the recess or the through-hole, the surface roughness Ra is 1.0 m or less, and the maximum height Rz is 100 m or less. It is preferable that the maximum height Rz is 10 m or less. Further, it is preferable that the surface roughness Ra is 0.5 m or less. According to the above-described configuration, it is possible to provide a ceramic circuit board having an excellent positionability of the conductive portion for mounting a semiconductor element.

The present invention discloses a method for coating and forming a novel material layer structure of a high-frequency circuit board, comprising the steps of: (1) coating a synthetic liquid film on a copper foil; (2) delivering the same to a tunnel oven for roasting, and forming a cured film on the copper foil to obtain a single-sided board; (3) coating a layer of synthetic liquid high-frequency material on the cured film; and (4) delivering the same to the tunnel oven for roasting until the synthetic liquid high-frequency material layer becomes a semi-cured high-frequency material layer so as to obtain a novel material layer structure of a high-frequency circuit board. An article prepared by performing the above methods is also disclosed. The prepared novel material layer structure of the high-frequency circuit board has the performance of high-speed transmission of high-frequency signals, and can adapt to the current high-frequency and high-speed trend from wireless network to terminal applications, especially for new 5G technology products. It can be used as a circuit board preparation material to make a single-layer circuit board, a multi-layer flexible circuit board and a multi-layer soft-hard combined board, which brings great convenience to circuit board preparation and simplifies the process.

In some embodiments, methods include drilling one or a plurality of PTHs with any industrial grade drill to fabricate holes with positive etch back, flooding the PTHs with a dilute solution of an acrylate monomer/oligomer containing an appropriate level of peroxide initiator, polymerizing the acrylate, and then rising the PTHs with the solvent used in the formulation of the acrylate material. In one embodiment, the printed circuit board may include a substrate comprising a plurality of metal layers separated by a plurality of insulating layers; a plurality of plated through holes formed in the substrate, each plated through hole comprising: recesses formed at each insulating layer, copper lands between the recesses, a polymer coating in each recess, and a metal layer lining the plated through hole.

The invention relates to a process chamber (10) for carrying out thermal processes in the manufacture of an electronic assembly (30), comprising the following: at least one opening (20) for introducing and/or removing the electronic assembly (30); a device (40) for supplying a gas; a controllable protection device (50) which is arranged on the opening (20) in order to reduce a leakage of gas from the process chamber, wherein the controllable protection device (50) comprises a first movable element (50A) as an integral piece which covers the width between the total width of the opening and the width of the electronic assembly; a device for detecting data relating to the dimensions of the electronic assembly (30); and a controller (60) which can control the protection device (50) on the basis of the data relating to the dimensions of the electronic assembly (30) such that when the electronic assembly (30) passes through the opening (20), a defined spacing is constantly maintained between the electronic assembly and the first movable element (50A).

A method for manufacturing a wiring board, including: forming a resist layer on a seed layer comprising a metal provided on a support body; forming a pattern including an opening to which the seed layer is exposed in the resist layer by light exposure and development of the resist layer, and forming a copper plating layer on the seed layer exposed into the opening by electrolytic plating, in this order. The arithmetic mean roughness Ra of the surface of the seed layer on a side opposite to the support body is 0.05 ?m or more and 0.30 ?m or less.

A substrate (1, 10) for electrical circuits, comprising at least one metal layer (2,3, 14) and a paper ceramic layer (11), which is joined face to face with the at least one metal layer (2,3, 14) and has a top side and bottom side (11a, 11b), wherein the paper ceramic layer (11) has a large number of cavities in the form of pores. Especially advantageously, the at least one metal layer (2, 3, 14) is connected to the paper ceramic layer (11) by means of at least one glue layer (6, 6a, 6b), which is produced by applying at least one glue (6a, 6a, 6b, 6b) to the metal layer (2,3, 14) and/or to the paper ceramic layer (11), wherein the cavities in the form of pores in the paper ceramic layer (11) are filled at least at the surface by means of the applied glue (6a, 6a, 6b,6b).