Implementations of semiconductor packages may include: a substrate comprising a first side and a second side and a hole in the substrate. The hole extending from the first side to the second side of the substrate and positioned in a center of the substrate. The semiconductor packages may also include a bushing around the hole to the first side of the substrate. The semiconductor packages may also include a plurality of pin holders arranged and coupled on the substrate. The semiconductor package may also include a molding compound at least partially encapsulating the substrate, encapsulating a side surface of the bushing, and encapsulating a plurality of side surfaces of the plurality of pin holders.

A field-effect transistor (FET) and method of manufacture thereof include a gate, a pillar of grown on a top of the planar source and drain regions, and a conductive sheath flanking the pillar, the sheath is bent up, alongside, and over the gate.

A first and second antenna substrate are included in an advanced antenna package. Each antenna substrate includes a respective array of antenna elements disposed on a respective first surface of the substrate. A plurality of stand-off balls disposed between the first surfaces of first and second antenna substrates are bonded to the first surface of the first antenna substrate. A first sub-plurality of the stand-off balls are placed at positions in a peripheral region of the first and second antenna substrates. A second sub-plurality of the stand-off balls are placed at interior positions between antenna elements of the first and second antenna substrates. A plurality of adhesive pillars are disposed between and bond the first surfaces of first and second antenna substrates at a plurality of discrete selected locations. A first location of the discrete selected locations is in a peripheral region. A second location of the discrete selected locations is at an interior position between antenna elements. A method for fabricating the antenna package is also described.

Implementations of semiconductor packages may include: a substrate comprising a first side and a second side and a hole in the substrate. The hole extending from the first side to the second side of the substrate and positioned in a center of the substrate. The semiconductor packages may also include a bushing around the hole to the first side of the substrate. The semiconductor packages may also include a plurality of pin holders arranged and coupled on the substrate. The semiconductor package may also include a molding compound at least partially encapsulating the substrate, encapsulating a side surface of the bushing, and encapsulating a plurality of side surfaces of the plurality of pin holders.

Apparatuses and methods relating generally to a microelectronic package for wafer-level chip scale packaging with fan-out are disclosed. In an apparatus, there is a substrate having an upper surface and a lower surface opposite the upper surface. A microelectronic device is coupled to the upper surface with the microelectronic device in a face-up orientation. Wire bond wires are coupled to and extending away from the upper surface. Posts of the microelectronic device extend away from a front face thereof. Conductive pads are formed in the substrate associated with the wire bond wires for electrical conductivity.

In some examples, a semiconductor package includes a semiconductor die having a device side and a non-device side opposing the device side. The device side has a circuit formed therein. The package includes a first conductive member having a first surface coupled to the non-device side of the semiconductor die and a second surface opposing the first surface. The second surface is exposed to a top surface of the semiconductor package. The package includes a second conductive member exposed to an exterior of the semiconductor package and coupled to the device side of the semiconductor die. The package includes a plurality of wirebonded members coupled to the second surface of the first conductive member and exposed to the exterior of the semiconductor package. At least one of the wirebonded members in the plurality of wirebonded members has a gauge of at least 5 mils.

At least some embodiments of the present disclosure relate to an electronic structure. The package structure includes a lead frame, an electronic component, and a conductive wire physically and electrically connecting the electronic component to the lead frame. An elevation of a first end of the conductive wire is substantially equal to an elevation of a second end of the conductive wire.

An electronics package includes a support substrate, an electrical component having a first surface coupled to a first surface of the support substrate, and an insulating structure coupled to the first surface of the support substrate and sidewalls of the electrical component. The insulating structure has a sloped outer surface. A conductive layer encapsulates the electrical component and the sloped outer surface of the insulating structure. A first wiring layer is formed on a second surface of the support substrate. The first wiring layer is coupled to the conductive layer through at least one via in the support substrate.

Apparatuses and methods relating generally to a microelectronic package for wafer-level chip scale packaging with fan-out are disclosed. In an apparatus, there is a substrate having an upper surface and a lower surface opposite the upper surface. A microelectronic device is coupled to the upper surface with the microelectronic device in a face-up orientation. Wire bond wires are coupled to and extending away from the upper surface. Posts of the microelectronic device extend away from a front face thereof. Conductive pads are formed in the substrate associated with the wire bond wires for electrical conductivity.

In a method of manufacturing a semiconductor memory device, a plurality of first conductive structures including a first conductive pattern and a hard mask are sequentially stacked on a substrate. A plurality of preliminary spacer structures including first spacers, sacrificial spacers and second spacers are sequentially stacked on sidewalls of the conductive structures. A plurality of pad structures are formed on the substrate between the preliminary spacer structures, and define openings exposing an upper portion of the sacrificial spacers. A first mask pattern is formed to cover surfaces of the pad structures, and expose the upper portion of the sacrificial spacers. The sacrificial spacers are removed to form first spacer structures having respective air spacers, and the first spacer structures include the first spacers, the air spacers and the second spacers sequentially stacked on the sidewalls of the conductive structures.