The present disclosure is directed to semiconductor packages that include a molding compound having at least one raised portion that extends outward from the package. In some embodiments, the semiconductor packages have a plurality of raised portions, and a plurality of conductive layers are on the plurality of raised portions. The plurality of raised portions and the plurality of conductive layers are utilized to mount the semiconductor packages to an external electronic device (e.g., a printed circuit board (PCB), another semiconductor package, an external electrical connection, etc.). In some embodiments, the semiconductor packages have a single raised portion with a plurality of conductive layers that are on the single raised portion. The single raised portion and the plurality of conductive layers are utilized to mount the semiconductor packages to the external electronic device. The plurality of conductive layers on the plurality of raised portions or the single raised portion may be formed by a laser direct structuring (LDS) process.

A semiconductor package includes: a redistribution substrate including a connection via and a redistribution layer electrically connected to each other, and a redistribution pad electrically connected to the redistribution layer by the connection via, a space pattern separating at least some of the redistribution pads from each other, a dummy metal pattern at least partially surrounded by the space pattern, and a degassing opening passing through at least one of the redistribution pad and the dummy metal pattern; a connection bump electrically connected to the redistribution pad; and a semiconductor chip on the redistribution substrate and including a connection pad electrically connected to the redistribution layer, the redistribution pad including a plurality of protrusions protruding from the same plane in directions different from each other and having a corner having a rounded shape, and the dummy metal pattern includes branch patterns each extending in directions different from one another.

A semiconductor package including a plurality of semiconductor devices, an insulating layer, and a redistribution layer is provided. The insulating layer is disposed over the semiconductor device. The redistribution layer is disposed over the insulating layer and electrically connected to the semiconductor device. The redistribution layer includes a conductive line portion. The semiconductor package has a stitching zone, and the insulating layer has a ridge structure on a surface away from the semiconductor device and positioned within the stitching zone.

A chip package and method for fabricating the same are provided that includes an off-die inductor. The off-die inductor is disposed in a redistribution layer formed on a bottom surface of an integrated circuit (IC) die. The redistribution layer is connected to a package substrate to form the chip package.

A semiconductor device structure includes a silicon layer disposed over a first semiconductor die, and a first mask layer disposed over the silicon layer. The semiconductor device structure also includes a second semiconductor die disposed over the first mask layer, and a through silicon via penetrating through the silicon layer and the first mask layer. A bottom surface of the through silicon via is greater than a top surface of the through silicon via, and the top surface of the through silicon via is greater than a cross-section of the through silicon via between and parallel to the top surface and the bottom surface of the through silicon via.

An electronic package is provided, where a circuit layer and a metal layer having a plurality of openings are formed on a dielectric layer of a circuit portion to reduce the area ratio of the metal layer to the dielectric layer, so as to reduce stress concentration and prevent warping of the electronic package.

A semiconductor device includes lower circuit patterns on a lower substrate; lower bonding patterns on the lower circuit patterns, the lower bonding patterns including a conductive material and being electrically connected to the lower circuit patterns; upper bonding patterns on and contacting the lower bonding patterns, and including a conductive material; a passive device on the upper bonding patterns, and including a conductive material and contacting one of the upper bonding patterns; a gate electrode structure on the passive device, and including gate electrodes spaced apart from each other in a first direction, each of which extends in a second direction, and extension lengths in the second direction of the gate electrodes increasing from a lowermost level toward an uppermost level in a stepwise manner; a channel extending through at least a portion of the gate electrode structure; and an upper substrate on the channel.

A semiconductor package including a core substrate, a semiconductor chip in the core substrate and having chip pads, a redistribution wiring layer covering a lower surface of the core substrate and including redistribution wirings electrically connected to the chip pads and a pair of capacitor pads exposed from an outer surface of the redistribution wiring layer, conductive pastes on the capacitor pads, respectively, and a capacitor via the conductive pastes and having first and second outer electrodes on the capacitor pads, respectively, may be provided. Each of the capacitor pads includes a pad pattern exposed from the outer surface of the redistribution wiring layer, and at least one via pattern at a lower portion of the pad pattern and electrically connected to at least one of the redistribution wirings. The via pattern is eccentric by a distance from a center line of the pad pattern.

A semiconductor device includes a first stacked body including a plurality of first semiconductor chips stacked along a first direction, each of the first semiconductor chips being offset from the other first semiconductor chips along a second direction perpendicular to the first direction; a first columnar electrode connected to an electrode pad of the first stacked body, and extending in the first direction; a second stacked body including a plurality of second semiconductor chips stacked along the first direction, each of the second semiconductor chips being offset from the other second semiconductor chips along the second direction, the second stacked body having a height larger than the first stacked body and overlap at least a portion of the first stacked body when viewed from the top; and a second columnar electrode connected to an electrode pad of the second stacked body, and extending in the first direction.

Die reconstitution methods and dies with reconstituted contact bumps are described. In an embodiment, a die reconstitution method includes reconstituting a plurality of dies including first contact bumps of a first type, partially removing the first contact bumps, and forming second contact bumps of a second type on top of the partially removed first contact bumps, where the second type is different than the first type.