A semiconductor device includes a first passivation layer over a circuit and. conductive pad over the first passivation layer, wherein the conductive pad is electrically connected to the circuit. A second passivation layer is disposed over the conductive pad and the first passivation layer, and has a first opening and a second opening. The first opening exposes an upper surface of a layer that extends underneath the conductive pad, and the second opening exposes the conductive pad. A first insulating layer is disposed over the second passivation layer and filling the first and second openings. A through substrate via extends through the insulating layer, second passivation layer, passivation layer, and substrate. A side of the through substrate via and the second passivation layer have a gap that is filled with the first insulating layer. A conductive via extends through the first insulating layer and connecting to the conductive pad.

A method includes forming a release film over a carrier, attaching a device over the release film through a die-attach film, encapsulating the device in an encapsulating material, performing a planarization on the encapsulating material to expose the device, detaching the device and the encapsulating material from the carrier, etching the die-attach film to expose a back surface of the device, and applying a thermal conductive material on the back surface of the device.

A semiconductor package is disclosed. The semiconductor package may include a first redistribution substrate including a first insulating layer and a first redistribution pattern, a lower semiconductor chip mounted on the first redistribution substrate, a conductive structure disposed on the first redistribution substrate and horizontally spaced apart from the lower semiconductor chip, a first mold layer interposed between the first redistribution substrate and the second redistribution substrate to cover the lower semiconductor chip and the conductive structure, a second redistribution substrate on the first redistribution substrate, the second redistribution substrate including a second insulating layer and a second redistribution pattern, a first heat-dissipation pattern interposed between the lower semiconductor chip and the second insulating layer, and a heat-dissipation pad on the conductive structure. A top surface of the first heat-dissipation pattern may be located at a level higher than a top surface of the conductive structure.

A package structure is provided. The package structure includes a through substrate via structure, a first stacked die package structure, an underfill layer, and a package layer. The through substrate via structure is formed over a substrate. The first stacked die package structure is over the through substrate via structure. The first stacked die package structure includes a plurality of memory dies. The underfill layer is over the first stacked die package structure. The underfill layer includes a first protruding portion that extends below a top surface of the through substrate via structure. The package layer is over the underfill layer. The package layer has a second protruding portion that extends below the top surface of the through substrate via structure.

A semiconductor device and method of manufacture are provided whereby an interposer and a first semiconductor device are placed onto a carrier substrate and encapsulated. The interposer comprises a first portion and conductive pillars extending away from the first portion. A redistribution layer located on a first side of the encapsulant electrically connects the conductive pillars to the first semiconductor device.

A package structure is provided. The package structure includes a through substrate via structure, a first stacked die package structure, an underfill layer, and a package layer. The through substrate via structure is formed over a substrate. The first stacked die package structure is over the through substrate via structure, wherein the first stacked die package structure comprises a plurality of memory dies. The underfill layer is over the first stacked die package structure. the package layer is over the underfill layer, wherein the package layer has a protruding portion that extends below a top surface of the through substrate via structure.

Certain aspects of the present disclosure generally relate to an integrated circuit assembly. One example integrated circuit assembly generally includes a first reconstituted assembly, a second reconstituted assembly, and a third reconstituted assembly. The first reconstituted assembly comprises at least one passive component and a first bonding layer. The second reconstituted assembly is disposed above the first reconstituted assembly and comprises one or more first semiconductor dies, a second bonding layer bonded to the first bonding layer of the first reconstituted assembly, and a third bonding layer. The third reconstituted assembly is disposed above the second reconstituted assembly and comprises one or more second semiconductor dies and a fourth bonding layer bonded to the third bonding layer of the second reconstituted assembly.

A semiconductor device is provided. The semiconductor device includes a first hard macro; a second hard macro spaced apart from the first hard macro in a first direction by a first distance; a head cell disposed in a standard cell area between the first hard macro and the second hard macro, the head cell being configured to perform power gating of a power supply voltage provided to one from among the first hard macro and the second hard macro; a plurality of first ending cells disposed in the standard cell area adjacent to the first hard macro; and a plurality of second ending cells disposed in the standard cell area adjacent to the second hard macro, the head cell not overlapping the plurality of first ending cells and the plurality of second ending cells.

A semiconductor module comprises a semiconductor device; a substrate, on which the semiconductor device is attached; a molded encasing, into which the semiconductor device and the substrate are molded; at least one power terminal partially molded into the encasing and protruding from the encasing, which power terminal is electrically connected with the semiconductor device; and an encased circuit board at least partially molded into the encasing and protruding over the substrate in an extension direction of the substrate, wherein the encased circuit board comprises at least one receptacle for a pin, the receptacle being electrically connected via the encased circuit board with a control input of the semiconductor device.

In an embodiment, a structure includes: a graphics processor device; a passive device coupled to the graphics processor device, the passive device being directly face-to-face bonded to the graphics processor device; a shared memory device coupled to the graphics processor device, the shared memory device being directly face-to-face bonded to the graphics processor device; a central processor device coupled to the shared memory device, the central processor device being directly back-to-back bonded to the shared memory device, the central processor device and the graphics processor device each having active devices of a smaller technology node than the shared memory device; and a redistribution structure coupled to the central processor device, the shared memory device, the passive device, and the graphics processor device.