A semiconductor device with a connection pad in a substrate, the connection pad having an exposed surface made of a metallic material that diffuses less readily into a dielectric layer than does a metal of a wiring layer connected thereto.

The present disclosure provides a packaging method, including: providing a first semiconductor substrate; forming a bonding region on the first semiconductor substrate, wherein the bonding region of the first semiconductor substrate includes a first bonding metal layer and a second bonding metal layer; providing a second semiconductor substrate having a bonding region, wherein the bonding region of the second semiconductor substrate includes a third bonding layer; and bonding the first semiconductor substrate to the second semiconductor substrate by bringing the bonding region of the first semiconductor substrate in contact with the bonding region of the second semiconductor substrate; wherein the first and third bonding metal layers include copper (Cu), and the second bonding metal layer includes Tin (Sn). An associated packaging structure is also disclosed.

An integrated circuit package is disclosed. The integrated circuit package includes a first integrated circuit die, a second integrated circuit die, an organic substrate, wherein both the first integrated circuit die and the second integrated circuit die are connected to the organic substrate, a multi-die interconnect bridge (EMIB) embedded within the organic substrate, and a termination resistor associated with a circuit in the first integrated circuit die, wherein the termination resistor is located within the multi-die interconnect bridge embedded within the organic substrate.

Embodiments of the present disclosure are directed towards an integrated circuit (IC) package including a first die at least partially embedded in a first encapsulation layer and a second die at least partially embedded in a second encapsulation layer. The first die may have a first plurality of die-level interconnect structures disposed at a first side of the first encapsulation layer. The IC package may also include a plurality of electrical routing features at least partially embedded in the first encapsulation layer and configured to route electrical signals between a first and second side of the first encapsulation layer. The second side may be disposed opposite to the first side. The second die may have a second plurality of die-level interconnect structures that may be electrically coupled with at least a subset of the plurality of electrical routing features by bonding wires.

Disclosed are a system-on-chip integrated packaging structure, a manufacturing method therefor and a three-dimensional stacked device. The system-on-chip integrated packaging structure includes: a substrate, a chip, a first electrical connection structure and a second electrical connection structure. A front surface of the substrate is provided with a recess and a via welding pad, and a back surface of the substrate is provided with a conductive via extending to the via welding pad. The chip is embedded in the recess, and a chip welding pad is disposed on a surface of the chip away from a bottom surface of the recess. Different chips may be electrically connected by means of the first electrical connection structure and the second electrical connection structure, which is conducive to form a three-dimensional stacked structure with high-density interconnection, miniaturized packaging and thinning.

Structures for a static random access memory bit cell and methods of forming a structure for a static random access memory bit cell. The structure includes a first field-effect transistor on a first substrate and a second field-effect transistor on a second substrate. The first field-effect transistor includes a first gate, and the second field-effect transistor includes a second gate. The structure further includes a first interconnect structure on the first substrate and a second interconnect structure on the second substrate. The first interconnect structure includes a first metal feature connected to the first gate, and the first metal feature has a first surface. The second interconnect structure includes a second metal feature connected to the second gate, and the second metal feature has a second surface that is connected to the first surface of the first metal feature.

A semiconductor device has a first semiconductor package including a substrate and an encapsulant deposited over the substrate. An adhesive tape is disposed on the encapsulant. A conductive via is formed by trench cutting through the adhesive tape and encapsulant to expose the substrate. A second semiconductor package is disposed over the adhesive tape opposite the first semiconductor package. The first semiconductor package and second semiconductor package are bonded together by the adhesive tape.

A semiconductor device includes a multi-layer board which a wiring pattern and a grounding pattern are formed. A plurality of semiconductor elements are mounted on the multi-layer board. An insulating sealing member is provided on the multi-layer board and is covering the plurality of semiconductor elements. A metal film is provided on the insulating sealing member. An in-groove metal is provided in contact with a plurality of grooves extending from a side-surface upper end of the insulating sealing member to a side-surface lower end of the multi-layer board. An in-hole metal is provided in an inner wall of a hole penetrating through the insulating sealing member and is extending to the multi-layer board. The in-hole metal is contacting with the metal film and the grounding pattern.

Integrated circuit (IC) assemblies with stacked compute logic and memory dies, and associated systems and methods, are disclosed. One example IC assembly includes a compute logic die and a stack of memory dies provided above and coupled to the compute logic die, where one or more of the memory dies closest to the compute logic die include memory cells with transistors that are thin-film transistors (TFTs), while one or more of the memory dies further away from the compute logic die include memory cells with non-TFT transistors. Another example IC assembly includes a similar stack of compute logic die and memory dies where one or more of the memory dies closest to the compute logic die include static random-access memory (SRAM) cells, while one or more of the memory dies further away from the compute logic die include memory cells of other memory types.

An electronic device includes: (i) a first chiplet including a first seal ring, which is disposed in metal layers embedded between a first surface of the first chiplet, and a first substrate of the first chiplet, (ii) a second chiplet including a second seal ring, which is disposed in metal layers embedded between a second surface of the second chiplet, and a second substrate of the second chiplet, and (iii) a third seal ring, which surrounds the first and second chiplets and is disposed in a dielectric substrate extrinsic to the metal layers and overlaying the first and second surfaces of the first and second chiplets.