An electronic component includes a plurality of laminated insulating layers, one or more surface conductors formed on a surface of the insulating layer, and an internal conductor formed at a boundary portion between the adjacent insulating layers. A thickness of the surface conductor is larger than a thickness of a thinnest layer of the insulating layers and larger than a thickness of the internal conductor.

A semiconductor package includes a circuit board, an interposer structure on the circuit board, a first semiconductor chip and a second semiconductor chip on the interposer structure, the first and the second semiconductor chips electrically connected to the interposer structure and spaced apart from each other, and a mold layer between the first and second semiconductor chips, the mold layer separating the first and second semiconductor chips. A slope of a side wall of the mold layer is constant as the side wall extends away from an upper side of the interposer structure, and an angle defined by a bottom side of the mold layer and the side wall of the mold layer is less than or equal to ninety degrees.

A described example includes: a reconstituted semiconductor device flip chip mounted on a device side surface of a package substrate, the package substrate having terminals for connecting the package substrate to a circuit board, the reconstituted semiconductor device further including: a semiconductor die mounted in a dielectric layer and having bond pads spaced from one another by at least a first pitch distance that is less than 100 microns; a redistribution layer formed over the bond pads having conductors in passivation layers; solder bumps on the redistribution layer coupled to the bond pads of the semiconductor die, the solder bumps spaced from one another by at least a second pitch distance that is greater than the first pitch distance; and solder joints formed between the package substrate and the solder bumps, the solder joints coupling the package substrate to the semiconductor die in the reconstituted semiconductor device.

An electronic device includes a substrate, a semiconductor die, and a molded package structure that encloses a portion of the semiconductor die and extends to a portion of the substrate. A sensor surface extends along a side of the semiconductor die, and conductive terminals extend outward from the side and have ends soldered to conductive features of the substrate. The side of the semiconductor die is spaced apart from the substrate and the conductive terminals forming a cage structure that laterally surrounds the sensor surface. The molded package structure has a cavity that extends between the sensor surface and the substrate, and the cavity extends in an interior of a cage structure formed by the conductive terminals.

A region of a sealing part is effectively utilized. -A semiconductor device includes a semiconductor element, a substrate, a sealing part, and a cavity region. The substrate included in this semiconductor device is disposed adjacent to a bottom surface of the semiconductor element. The sealing part included in this semiconductor device is formed in a shape that covers an upper surface that is a surface facing the bottom surface of the semiconductor element, and seals the semiconductor element. The cavity region included in this semiconductor device is a region disposed in the sealing part and formed with a cavity.

A fan-out package includes at least one semiconductor die attached to an interposer structure. a molding compound die frame laterally surrounding the at least one semiconductor die and including a molding compound material, and at least one stress buffer structure located on the interposer structure and including a stress buffer material having a first Young's modulus. The molding compound die frame includes a molding compound material having a second Young's modulus that is greater than the first Young's modulus.

Devices and methods of manufacture for a hybrid interposer including a molding structure within a semiconductor device. A semiconductor device may include a semiconductor die, a package substrate, and a hybrid interposer positioned between the semiconductor die and the package substrate. The hybrid interposer may include a molding material layer, and an integrated device positioned within the molding interposer layer. The hybrid interposer may further include an organic material layer, and a non-organic material layer. The molding material layer may include an epoxy molding compound (EMC). The organic material layer may include a dielectric polymer material. The non-organic material layer may include a silicon-based dielectric material.

A semiconductor structure includes a semiconductor die containing an array of first bonding structures. Each of the first bonding structures includes a first metal pad located within a dielectric material layer and a basin-shaped underbump metallization (UBM) pad located within a respective opening in a passivation dielectric layer and contacting the first metal pad. An interposer includes an array of second bonding structures, wherein each of the second bonding structures includes an underbump metallization (UBM) pillar having a respective cylindrical shape. The semiconductor die is bonded to the interposer through an array of solder material portions that are bonded to a respective one of the first-type bonding structures and to a respective one of the second-type bonding structures.

A semiconductor device includes a lead frame having a first principal surface which includes a recess, and a second principal surface opposite to the first principal surface, a relay board, disposed in the recess, and having a third principal surface, and a fourth principal surface opposite to the third principal surface, wherein the fourth principal surface opposes a bottom surface of the recess, a first semiconductor chip disposed on the third principal surface, a first conductive material connecting the lead frame and the relay board, and a second conductive material connecting the relay board and the first semiconductor chip. A distance between the second principal surface and the third principal surface is less than or equal to a distance between the second principal surface and the first principal surface.

A die stacking structure, a semiconductor package and a method for manufacturing the die stacking structure are provided. The die stacking structure includes a first device die; second device dies, bonded onto the first device die, and arranged side-by-side; a gap profile modifier, laterally enclosing bottommost portions of the second device dies, wherein a thickness of the gap profile modifier gradually decreases away from sidewalls of the second device dies; and a dielectric material, covering the gap profile modifier and laterally surrounding the second device dies.