A micro-device structure includes a substrate having a substrate surface and a substrate contact disposed on or in the substrate surface, a cavity extending into the substrate from the substrate surface, a micro-device disposed in the cavity, the micro-device comprising a micro-device contact, a planarization layer disposed over at least a portion of the substrate, and an electrode disposed at least partially over or on the planarization layer and electrically connected to the micro-device contact.

A semiconductor device architecture includes a silicon substrate having sidewalls that are passivated by encapsulating the sidewalls in dielectric materials having high electric field strength. Encapsulating all the sidewalls using high field strength dielectric materials eliminates electrical paths in air or vacuum and confines the electric fields in these high field strength materials, increasing the breakdown voltage relative to unencapsulated devices and allowing the device to withstand greater standoff voltages. In some cases, encapsulating the sidewalls in this manner can allow the device to withstand voltages of 500V or greater.

A method includes bonding a first package component over a second package component, dispensing a first underfill between the first package component and the second package component, and bonding a third package component over the second package component. A second underfill is between the third package component and the second package component. The first underfill and the second underfill are different types of underfills.

Disclosed embodiments include composite-bridge die-to-die interconnects that are on a die side of an integrated-circuit package substrate and that contacts two IC dice and a passive device that is in a molding material, where the molding material also contacts the two IC dice.

A method includes providing a carrier, mounting a plurality of semiconductor dies on the carrier, forming a region of electrically insulating encapsulant material on the carrier that covers each of the semiconductor dies, removing sections of the encapsulant material to form gaps in the region of electrically insulating encapsulant material between each of the semiconductor dies, forming electrically conductive material within the gaps, and singulating the region of electrically insulating encapsulant material along each of the gaps to form a plurality of discrete encapsulant bodies. Each of the packaged semiconductor devices comprises a sidewall-facing terminal that is disposed on a sidewall of the encapsulant body. For each of the packaged semiconductor devices each of the sidewall-facing terminals is electrically connected to the semiconductor die of the respective packaged semiconductor device. Each of the sidewall-facing terminals of each packaged semiconductor device is provided from the electrically conductive material formed within the gaps.

A semiconductor device package and a method of manufacturing the same are provided. The semiconductor device package includes a first semiconductor element, a first redistribution layer, a second redistribution layer, and a conductive via. The first semiconductor element has a first active surface and a first back surface opposite to the first active surface. The first redistribution layer is disposed adjacent to the first back surface of the first semiconductor element. The second redistribution layer is disposed adjacent to the first active surface of the first semiconductor element. The conductive via is disposed between the first redistribution layer and the second redistribution layer, where the conductive via inclines inwardly from the second redistribution layer to the first redistribution layer.

In an embodiment, a method for manufacturing and passivating a die includes providing the die having an active frontside including a protrusion, the protrusion configured for electrically contacting the die, covering a portion of the protrusion by a passivation tape before applying a passivation layer, applying the passivation layer on all sides of the die including the frontside and its protrusion in one single process, except on the portion covered by the passivation tape and detaching the passivation tape from the covered portion of the protrusion after applying the passivation layer to expose the portion of the protrusion which forms an electrical contact area.

In an embodiment, a device includes: a processor die including circuit blocks, the circuit blocks including active devices of a first technology node; a power gating die including power semiconductor devices of a second technology node, the second technology node larger than the first technology node; and a first redistribution structure including first metallization patterns, the first metallization patterns including power supply source lines and power supply ground lines, where a first subset of the circuit blocks is electrically coupled to the power supply source lines and the power supply ground lines through the power semiconductor devices, and a second subset of the circuit blocks is permanently electrically coupled to the power supply source lines and the power supply ground lines.

Semiconductor package includes interposer, dies, encapsulant. Each die includes active surface, backside surface, side surfaces. Backside surface is opposite to active surface. Side surfaces join active surface to backside surface. Encapsulant includes first material and laterally wraps dies. Dies are electrically connected to interposer and disposed side by side on interposer with respective backside surfaces facing away from interposer. At least one die includes an outer corner. A rounded corner structure is formed at the outer corner. The rounded corner structure includes second material different from first material. The outer corner is formed by backside surface and a pair of adjacent side surfaces of the at least one die. The side surfaces of the pair have a common first edge. Each side surface of the pair does not face other dies and has a second edge in common with backside surface of the at least one die.

A semiconductor package and a method of forming the same are provided. The semiconductor package includes a package substrate, a semiconductor device, an underfill element, and a groove. The semiconductor device is bonded to the surface of the package substrate through multiple electrical connectors. The underfill element is formed between the semiconductor device and the surface of the package substrate to surround and protect the electrical connectors. The underfill element includes a fillet portion that extends laterally beyond the periphery of the semiconductor device and is formed along the periphery of the semiconductor device. The groove is formed in the fillet portion and spaced apart from the periphery of the semiconductor device.