Described are microelectronic devices including a substrate formed with multiple build-up layers, and having at least one build-up layer formed of a fiber-containing material. A substrate can include a buildup layers surrounding an embedded die, or outward of the build-up layer surrounding the embedded die that includes a fiber-containing dielectric. Multiple build-up layers located inward from a layer formed of a fiber-containing dielectric will be formed of a fiber-free dielectric.

Provided is a terminal plate according to an embodiment including: a first plate portion for being connected to a first semiconductor element; a second plate portion for being connected to a second semiconductor element; a third plate portion provided above the first plate portion and the second plate portion; a first connecting portion provided between the first plate portion and the third plate portion and connecting the first plate portion and the third plate portion; a second connecting portion provided between the second plate portion and the third plate portion and connecting the second plate portion and the third plate portion; a fourth plate portion provided above the first plate portion and the second plate portion and provided on the opposite side of the third plate portion with interposing the first and second plate portions; a third connecting portion provided between the first plate portion and the fourth plate portion and connecting the first plate portion and the fourth plate portion; a fourth connecting portion provided between the second plate portion and the fourth plate portion and connecting the second plate portion and the fourth plate portion; and a fifth plate portion provided above the fourth plate portion, the fifth plate portion connected to the fourth plate portion, and the fifth plate portion having a hole.

A semiconductor device includes a base and a conductive layer to form a composite substrate. The conductive layer covers a surface of the base. The semiconductor device also includes a dielectric layer covering the conductive layer. The conductive layer is disposed between the dielectric layer and the base. The semiconductor device further includes a GaN-containing composite layer, a gate electrode disposed over the GaN-containing composite layer, a source electrode and a drain electrode disposed on the GaN-containing composite layer. The source electrode and the drain electrode are disposed at two opposite sides of the gate electrode. In addition, a method for manufacturing the semiconductor device with a composite substrate is provided.

There is a problem that the reliability of insulation is lowered. A length L2 from a center P of a conductor layer 334 to a peripheral edge portion of an insulating member 333 is formed to be longer than a length L1 from the center P of the conductor layer 334 to a peripheral edge portion of a protruding portion 307a of a base member 307. In other words, a base end surface 308 of the peripheral edge portion of the protruding portion 307a is located on an inner side with respect to an insulating member end surface 336 of the peripheral edge portion of the insulating member 333. Further, the insulating member end surface 336 of the insulating member 333 and a conductor layer end surface 344 of the conductor layer form an end surface at the same position. Since the base end surface 308 of the peripheral edge portion of the protruding portion 307a is located on the inner side with respect to the insulating member end surface 336 of the peripheral edge portion of the insulating member 333 in this manner, an insulation distance can be secured.

The present disclosure relates to a component structure, a power module and a power module assembly structure having the component structure. The component structure comprises: a first bus bar, having one end extending to a first plane to form a first connecting terminal; a second bus bar, comprising a front portion of the second bus bar and a rear portion of the second bus bar, wherein the front portion of the second bus bar is laminated in parallel with the first bus bar, and the rear portion of the second bus bar is extended to a second plane to form a second connecting terminal; and an external circuit comprising a third bus bar, wherein the third bus bar is settled in parallel with the rear portion of the second bus bar, to reduce a parasitic inductance between the first connecting terminal and the second connecting terminal.

A package structure is disclosed, the package structure includes a substrate, a chip, a bonding layer, and a coating. A plurality of grooves are disposed on the substrate. Silver bonding materials are disposed in the grooves and on a surface of the substrate, to form the bonding layer. The chip is connected to the substrate by using the bonding layer. The grooves are symmetrically arranged along a first and a second axis that are perpendicular to each other, a vertical projection of the chip on the substrate is centrosymmetric about the first and the second axis, and the vertical projection of the chip on the substrate covers a partial area of an outer-ring groove which faces a periphery of the chip. The coating covers a surface that is of the bonding layer and not in contact with the substrate or the chip, used to prevent migration of silver ions.

According to one embodiment, a semiconductor device includes at least a package substrate, an external electrode, a mounting substrate, and a mounting electrode. A signal connection point of the external electrode is provided at an end portion in a longitudinal direction of the external electrode. A signal connection point of the mounting electrode is provided at an end portion of the mounting electrode. The end portion of the mounting electrode is opposite to the signal connection point of the external electrode facing to the mounting electrode in the longitudinal direction.

The present disclosure relates to a component structure, a power module and a power module assembly structure having the component structure. The component structure comprises: a first bus bar, having one end extending to a first plane to form a first connecting terminal; a second bus bar, comprising a front portion of the second bus bar and a rear portion of the second bus bar, wherein the front portion of the second bus bar is laminated in parallel with the first bus bar, and the rear portion of the second bus bar is extended to a second plane to form a second connecting terminal; and an external circuit comprising a third bus bar, wherein the third bus bar is settled in parallel with the rear portion of the second bus bar, to reduce a parasitic inductance between the first connecting terminal and the second connecting terminal.

A method of manufacturing a light emitting element mounting base member includes: providing a first insulating member in a plate shaped having at least one recess portion or at least one through-hole; disposing in the recess portion or in the through-hole a light blocking resin and a plurality of core members each equipped with a second insulating member having light reflectivity on each surface of a plurality of electrical conductor cores; and exposing at least one of the surface of the electrical conductor cores from the second insulating members by removing each part of at least one of the second insulating members.

A semiconductor device comprises a generally planar semiconductor chip. The semiconductor chip comprises a first side and second side opposite the first side. The first side is associated with a source conductive pad. The second side is associated with a drain conductive pad. A gate pad overlies a portion of the first side. A source terminal comprises a metallic strip assembly with a series of pocket chambers spaced apart from each other and partially filled with a phase-change material filling. A drain terminal is spaced apart from the source terminal by a dielectric layer. The source terminal is bonded to the source conductive pad via a bonding interface material.