A DRAM chiplet structure is provided. The DRAM chiplet structure includes a first hybrid bonding structure, a DRAM interface structure, and a first DRAM core structure. The first hybrid bonding structure has a first surface and a second surface. The DRAM interface structure is in contact with the first surface of the first hybrid bonding structure. The first DRAM core structure is in contact with the second surface of the first hybrid bonding structure. The DRAM interface structure is electrically connected to the first DRAM core structure through the first hybrid bonding structure.

In one embodiment, a semiconductor device includes a lower interconnect layer including a plurality of lower interconnects, and a plurality of lower pads provided on the lower interconnects. The device further includes a plurality of upper pads provided on the lower pads and being in contact with the lower pads, and an upper interconnect layer including a plurality of upper interconnects provided on the upper pads. The lower pads include a plurality of first pads and a plurality of second pads. The upper pads include a plurality of third pads provided on the second pads and a plurality of fourth pads provided on the first pads, a lower face of each third pad is larger in area than a upper face of each second pad, and a lower face of each fourth pad is smaller in area than a upper face of each first pad.

A method for a through-silicon-via (TSV) connector includes: providing a semiconductor wafer with a silicon substrate, wherein the semiconductor wafer has a frontside and a backside opposite to the frontside thereof; forming multiple holes in the silicon substrate of the semiconductor wafer; forming a first insulating layer at a sidewall and bottom of each of the holes; forming a metal layer over the semiconductor wafer and in each of the holes; polishing the metal layer outside each of the holes to expose a frontside surface of the metal layer in each of the holes; forming multiple metal bumps or pads each on the frontside surface of the metal layer in at least one of the holes; grinding a backside of the silicon substrate of the semiconductor wafer to expose a backside surface of the metal layer in each of the holes, wherein the backside surface of the metal layer in each of the holes and a backside surface of the silicon substrate of the semiconductor wafer are coplanar; and cutting the semiconductor wafer to form multiple through-silicon-via (TSV) connectors.

A wafer-to-wafer bonding structure includes a first wafer including a first conductive pad in a first insulating layer and a first barrier layer surrounding a lower surface and side surfaces of the first conductive pad, a second wafer including a second conductive pad in a second insulating layer and a second barrier layer surrounding a lower surface and side surfaces of the second conductive pad, the second insulating layer being bonded to the first insulating layer, and at least a portion of an upper surface of the second conductive pad being partially or entirely bonded to at least a portion of an upper surface of the first conductive pad, and a third barrier layer between portions of the first and second wafers where the first and second conductive pads are not bonded to each other.

A semiconductor device includes a semiconductor substrate, a dielectric structure, an electrical insulating and thermal conductive layer and a circuit layer. The electrical insulating and thermal conductive layer is disposed over the semiconductor substrate. The dielectric structure is disposed over the electrical insulating and thermal conductive layer, wherein a thermal conductivity of the electrical insulating and thermal conductive layer is substantially greater than a thermal conductivity of the dielectric structure. The circuit layer is disposed in the dielectric structure.

A method includes forming a first package component, which formation process includes forming a first plurality of openings in a first dielectric layer, depositing a first metallic material into the first plurality of openings, performing a planarization process on the first metallic material and the first dielectric layer to form a plurality of metal pads in the first dielectric layer, and selectively depositing a second metallic material on the plurality of metal pads to form a plurality of bond pads. The first plurality of bond pads comprise the plurality of metal pads and corresponding parts of the second metallic material. The first package component is bonded to a second package component.

A package structure and method of manufacturing is provided, whereby a bonding dielectric material layer is provided at a back side of a wafer, a bonding dielectric material layer is provided at a front side of an adjoining wafer, and wherein the bonding dielectric material layers are fusion bonded to each other.

In an embodiment, a method includes: bonding a back side of a first memory device to a front side of a second memory device with dielectric-to-dielectric bonds and with metal-to-metal bonds; after the bonding, forming first conductive bumps through a first dielectric layer at a front side of the first memory device, the first conductive bumps raised from a major surface of the first dielectric layer; testing the first memory device and the second memory device using the first conductive bumps; and after the testing, attaching a logic device to the first conductive bumps with reflowable connectors.

In an embodiment, a device includes: an interposer; a first integrated circuit device bonded to the interposer with dielectric-to-dielectric bonds and with metal-to-metal bonds; a second integrated circuit device bonded to the interposer with dielectric-to-dielectric bonds and with metal-to-metal bonds; a buffer layer around the first integrated circuit device and the second integrated circuit device, the buffer layer including a stress reduction material having a first Young's modulus; and an encapsulant around the buffer layer, the first integrated circuit device, and the second integrated circuit device, the encapsulant including a molding material having a second Young's modulus, the first Young's modulus less than the second Young's modulus.

A method of manufacturing a bonded substrate stack includes: providing a first substrate having a first hybrid interface layer, the first hybrid interface layer including a first insulator and a first metal; and providing a second substrate having a second hybrid interface layer, the second hybrid interface layer including a second insulator and a second metal. The hybrid interface layers are surface-activated to generate dangling bonds on the hybrid interface layers. The surface-activated hybrid interface layers are brought into contact, such that the dangling bonds of the first hybrid interface layer and the dangling bonds of the second hybrid interface layer bond together to form first insulator to second insulator bonds and first metal to second metal bonds.