A high thermal conductivity prepreg is provided. The high thermal conductivity prepreg includes a high thermal conductivity reinforcing material and a dielectric material layer formed on the surface of the high thermal conductivity reinforcing material, wherein the high thermal conductivity reinforcing material is prepared by a process which includes the following steps: (a) providing a precursor aqueous solution, the precursor aqueous solution includes a precursor selected from the group of organic salts, inorganic salts, and combinations thereof; (b) subjecting the precursor aqueous solution to a hydrolysis reaction to form an intermediate product aqueous solution; (c) subjecting the intermediate product aqueous solution to a condensation polymerization reaction to form a pretreatment solution; (d) impregnating a reinforcing material with the pretreatment solution; and (e) oven-drying the impregnated reinforcing material to obtain the high thermal conductivity reinforcing material.

A flexible circuit board protection layer includes a flexible backing, a first flexible layer arranged on one side of the flexible backing, and a second flexible layer arranged on one side of the first flexible layer that is distant from the flexible backing. The first flexible layer includes first strip sections that are arranged parallel and spaced from each other. The second flexible layer includes second strip sections that are arranged parallel and spaced from each other. The first strip sections have an extension direction that is perpendicular to an extension direction of the second strip sections. To use in an OLED display device, the flexible circuit board is arranged between two such flexible circuit board protection layers and then disposed on one side of the display panel in order effectively protect the flexible circuit board and prevent the flexible circuit board from being damaged during flexing.

A fluorocarbon resin composition is applicable to produce a prepreg for use in making a high-frequency circuit board, including a polytetrafluoroethylene resin; a fluorine-containing copolymer of poly fluoroalkoxy or fluorinated ethylene propylene; inorganic powders and an impregnation additive such as hydroxyethyl cellulos; resulted in that the prepreg is capable of increasing a plurality of times for proceeding impregnation-coating, the surface defects prone to occur on a fluorocarbon prepreg during drying, baking and sintering after impregnation are therefore improved at the same time.

A thermosetting resin composition and a prepreg and a metal foil-covered laminate made using same, the thermosetting resin composition comprising component (A): a solvent-soluble polyfunctional vinyl aromatic copolymer, the copolymer being a poly-functional vinyl aromatic copolymer having a stoctoal unit derived from monomers comprising divinyl aromatic compound (a) and ethyl vinyl aromatic compound (b); and component (B): a vinyl-containing organic silicone resin. The prepreg and metal foil-covered laminate made from the thermosetting resin composition have good toughness, and maintain a high glass transition temperature, a low water absorption, dielectric properties and humidity resistance, being suitable for the field of high-frequency and high-speed printed circuit boards and the processing of multilayer printed circuit boards.

An active ester compound that can form a cured product having excellent dielectric properties and copper foil adhesion properties is provided, a curable composition including the active ester compound is provided, and a cured product of the curable composition is provided. Also provided are a semiconductor encapsulating material, a printed wiring board, and a build-up film formed by using the curable composition. Specifically, an active ester compound is provided which includes a fluorinated hydrocarbon structural moiety and a plurality of aromatic ester structural moieties in the structure of the molecule and includes an aryloxycarbonyl structure or an arylcarbonyloxy structure at an end of the molecule, a curable composition including the active ester compound, and a cured product of the curable composition, and also provided are a semiconductor encapsulation material, a printed wiring board, and a build-up film formed by using the curable composition.

A printed circuit board including: an insulating material; a metal layer stacked on a surface of the insulating material; and a via hole passing through the metal layer and the insulating material. The metal layer decreases in thickness in a region adjacent to the via hole, and an interface between the insulating material and the metal layer includes a region that is directed toward the via hole.

A structure of phosphorous-containing functionalized poly(arylene ether), a preparation method thereof, and a composition prepared therefrom are provided. The curable (cross-linkable) composition includes an unsaturated monomer and a phosphorous-containing functionalized poly(arylene ether) having a polymerizable group and a molecular weight between 500 and 20,000. The composition provides excellent fluidity and fast curing rate. After curing, the composition exhibits excellent low dielectric coefficient and dielectric loss, high heat resistance and flame retardancy. It is suitable for prepregs, laminated sheets for printed circuits or the like.

To overcome the problem of the fiber weave effect desynchronizing differential signals in a pair of traces of approximately the same length in a printed circuit board, the pair of traces can be routed to traverse largely parallel paths that are above one another in the printed circuit board. The material between the paths can include weaved fiber bundles. The material on opposite sides of the paths, surrounding the pair of traces and the weaved fiber bundles, can include resin-rich material. As a result, the pair of traces are directly adjacent to the same materials, which can allow signals in the traces to propagate at the same speed, and prevent desynchronization of differential signals traversing the paths. The path length difference associated with traversing to different depths can be compensated with a relatively small in-plane diagonal jog of one of the traces.

In one embodiment, an apparatus includes a plurality of layers in a circuit board, each of the layers comprising a fiber weave, two plated holes extending through the layers and connecting two or more of the layers, and a non-plated hole interposed between the plated holes. The non-plated hole passes through a potential CAF (Conductive Anodic Filament) migration path along the fiber weave to prevent CAF formation between the plated holes.

A circuit board includes at least one prepreg including a fiber layer, the fiber layer being woven with a plurality of first fibers arranged in a first direction and a plurality of second fibers arranged in a second direction that is substantially perpendicular to the first direction, and a circuit layer on at least one of opposite surfaces of the at least one prepreg. The at least one prepreg has a length in the first direction greater than a length in the second direction, each of the plurality of first fibers is formed of or includes a filling yarn, and each of the plurality of second fibers is formed of or includes a warp yarn.