Integrated circuit (IC) packages employing split, double-sided IC metallization structures to facilitate a semiconductor die module employing stacked dice, and related fabrication methods are disclosed. Multiple IC dice in the IC package are stacked and bonded together in a back-to-back, top and bottom IC die configuration in an IC die module, which can minimize the height of the IC package. The metallization structure is split between separate top and bottom metallization structures adjacent to respective top and bottom surfaces of the IC die module to facilitate die-to-die and external electrical connections to the dice. The top and bottom metallization structures can be double-sided by exposing substrate interconnects on respective inner and outer surfaces for respective die and external electrical interconnections. In other aspects, a compression bond is included between the IC dice mounted together in a back-to-back configuration to further minimize the overall height of the IC package.

In one embodiment, an integrated device package is disclosed. The integrated device package can comprise a carrier an a molding compound over a portion of an upper surface of the carrier. The integrated device package can comprise an integrated device die mounted to the carrier and at least partially embedded in the molding compound, the integrated device die comprising active circuitry. The integrated device package can comprise a stress compensation element mounted to the carrier and at least partially embedded in the molding compound, the stress compensation element spaced apart from the integrated device die, the stress compensation element comprising a dummy stress compensation element devoid of active circuitry. At least one of the stress compensation element and the integrated device die can be directly bonded to the carrier without an adhesive.

A memory device includes a first electrically conductive line laterally extending along a first horizontal direction, a memory pillar structure overlying and contacting the first electrically conductive line, the memory pillar structure includes a vertical stack of a ferroelectric material plate and a selector material plate, and a second electrically conductive line laterally extending along a second horizontal direction and overlying and contacting the memory pillar structure.

A semiconductor device includes a first substrate structure having a first substrate, circuit elements disposed on the first substrate, and first bonding pads disposed on the circuit elements. A second substrate structure is connected to the first substrate structure. The second substrate structure includes a second substrate having first and second surfaces, first and second conductive layers spaced apart from each other, a pad insulating layer having an opening exposing a portion of the second conductive layer and gate electrodes stacked to be spaced apart from each other in a first direction and electrically connected to the circuit elements. First contact plugs extend on the second surface in the first direction and connect to the gate electrodes. A second contact plug extends on the second surface in the first direction and electrically connects to the second conductive layer. Second bonding pads electrically connect to the first and second contact plugs.

An electronic device with embedded access to a high-bandwidth, high-capacity fast-access memory includes (a) a memory circuit fabricated on a first semiconductor die, wherein the memory circuit includes numerous modular memory units, each modular memory unit having (i) a three-dimensional array of storage transistors, and (ii) a group of conductors exposed to a surface of the first semiconductor die, the group of conductors being configured for communicating control, address and data signals associated the memory unit; and (b) a logic circuit fabricated on a second semiconductor die, wherein the logic circuit also includes conductors each exposed at a surface of the second semiconductor die, wherein the first and second semiconductor dies are wafer-bonded, such that the conductors exposed at the surface of the first semiconductor die are each electrically connected to a corresponding one of the conductors exposed to the surface of the second semiconductor die. The three-dimensional array of storage transistors may be formed by NOR memory strings.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first die, a first conductive feature positioned in the first die, a second die positioned on the first die, a first mask layer positioned on the second die, a second mask layer positioned on the first mask layer, a conductive filler layer positioned penetrating the second mask layer, the first mask layer, and the second die, extending to the first die, and contacting the first conductive feature, isolation layers positioned between the conductive filler layer and the first die, between the conductive filler layer and the second die, and between the conductive filler layer and the first mask layer, and protection layers positioned between the conductive filler layer and the second mask layer and between the conductive filler layer and the first mask layer, and covering upper portions of the isolation layers.

A semiconductor structure includes an alternating stack of insulating layers and electrically conductive layers that alternate along a vertical direction, a memory opening vertically extending through the alternating stack, a memory opening fill structure located in the memory opening and including a vertical semiconductor channel and a vertical stack of memory elements, and a layer stack of an undoped semiconductor material layer and a source semiconductor layer. The undoped semiconductor material layer contacts a bottom end of the vertical semiconductor channel.

Provided are integrated circuit packages and methods of forming the same. An integrated circuit package includes at least one first die, a plurality of bumps, a second die and a dielectric layer. The bumps are electrically connected to the at least one first die at a first side of the at least one first die. The second die is electrically connected to the at least one first die at a second side of the at least one first die. The second side is opposite to the first side of the at least one first die. The dielectric layer is disposed between the at least one first die and the second die and covers a sidewall of the at least one first die.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers located over a carrier substrate. Memory stack structures vertically extend through the alternating stack. Each memory stack structure includes a respective vertical semiconductor channel and a respective memory film. A pass-through via structure vertically extends through a dielectric material portion that is adjacent to the alternating stack. The memory die can be bonded to a logic die containing peripheral circuitry for supporting operations of memory cells within the memory die. A distal end of each of the vertical semiconductor channels is physically exposed by removing the carrier substrate. A source layer is formed directly on the distal end each of the vertical semiconductor channels. A backside bonding pad or bonding wire is formed to be electrically connected to the pass-through via structure.

A package structure includes a plurality of stacked die units and an insulating encapsulant. The plurality of stacked die units is stacked on top of one another, where each of the plurality of stacked die units include a first semiconductor die, a first bonding chip. The first semiconductor die has a plurality of first bonding pads. The first bonding chip is stacked on the first semiconductor die and has a plurality of first bonding structure. The plurality of first bonding structures is bonded to the plurality of first bonding pads through hybrid bonding. The insulating encapsulant is encapsulating the plurality of stacked die units.