The present disclosure relates to thin-form-factor reconstituted substrates and methods for forming the same. The reconstituted substrates described herein may be utilized to fabricate homogeneous or heterogeneous high-density 3D integrated devices. In one embodiment, a silicon substrate is structured by direct laser patterning to include one or more cavities and one or more vias. One or more semiconductor dies of the same or different types may be placed within the cavities and thereafter embedded in the substrate upon formation of an insulating layer thereon. One or more conductive interconnections are formed in the vias and may have contact points redistributed to desired surfaces of the reconstituted substrate. The reconstituted substrate may thereafter be integrated into a stacked 3D device.

A semiconductor device includes a circuit substrate, a semiconductor package, and a metallic cover. The semiconductor package is disposed on the circuit substrate. The metallic cover is disposed over the semiconductor package and over the circuit substrate. The metallic cover comprises a lid and outer flanges. The lid overlies the semiconductor package. The outer flanges are disposed at edges of the lid, are connected with the lid, extend from the lid towards the circuit substrate, and face side surfaces of the semiconductor package. The lid has a first region that is located over the semiconductor package and is thicker than a second region that is located outside a footprint of the semiconductor package.

Semiconductor devices having electrical interconnections through vertically stacked semiconductor dies, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor assembly includes a die stack having a plurality of semiconductor dies. Each semiconductor die can include surfaces having an insulating material, a recess formed in at least one surface, and a conductive pad within the recess. The semiconductor dies can be directly coupled to each other via the insulating material. The semiconductor assembly can further include an interconnect structure electrically coupled to each of the semiconductor dies. The interconnect structure can include a monolithic via extending continuously through each of the semiconductor dies in the die stack. The interconnect structure can also include a plurality of protrusions extending from the monolithic via. Each protrusion can be positioned within the recess of a respective semiconductor die and can be electrically coupled to the conductive pad within the recess.

A semiconductor package includes a first die comprising an upper surface and a lower surface opposite to the upper surface. The first die includes a plurality of through-silicon vias (TSVs) penetrating through the first die. A second die is stacked on the upper surface of the first die. An interposer layer is disposed on the lower surface of the first die. An inductor is disposed in the interposer layer. The inductor comprises terminals directly coupled to the TSVs.

Semiconductor device assemblies having stacked semiconductor dies and electrically functional heat transfer structures (HTSs) are disclosed herein. In one embodiment, a semiconductor device assembly includes a first semiconductor die having a mounting surface with a base region and a peripheral region adjacent the base region. At least one second semiconductor die can be electrically coupled to the first semiconductor die at the base region. The device assembly can also include an HTS electrically coupled to the first semiconductor die at the peripheral region.

A nonvolatile memory device includes an upper insulating layer. A first substrate is on the upper insulating layer. An upper interlayer insulating layer is on the first substrate. A plurality of word lines is stacked on the first substrate in a first direction and extends through a partial portion of the upper interlayer insulating layer. A lower interlayer insulating layer is on the upper interlayer insulating layer. A second substrate is on the lower interlayer insulating layer. A lower insulating layer is on the second substrate. A dummy pattern is composed of dummy material. The dummy pattern is disposed in a trench formed in at least one of the first and second substrates. The trench is formed on at least one of a surface where the upper insulating layer meets the first substrate, and a surface where the lower insulating layer meets the second substrate.

A memory device includes: a first wafer including a first substrate, a plurality of first electrode layers and a plurality of first interlayer dielectric layers alternately stacked along first vertical channels projecting in a vertical direction on a top surface of the first substrate, and a dielectric stack comprising a plurality of dielectric layers and the plurality of first interlayer dielectric layers alternately stacked on the top surface of the first substrate; and a second wafer disposed on the first wafer, and including a second substrate, and a plurality of second electrode layers that are alternately stacked with a plurality of second interlayer dielectric layers along second vertical channels projecting in the vertical direction on a bottom surface of the second substrate and have pad parts overlapping with the dielectric stack in the vertical direction.

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.

A semiconductor package device includes a substrate, an electronic component, and a thermal conductive layer. The electronic component is disposed on the substrate and includes a first surface facing away from the substrate. The thermal conductive layer is disposed above the first surface of the electronic component. The thermal conductive layer includes a plurality of portions spaced apart from each other.

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.