A device comprises a first chip comprising a plurality of first interconnect structures over a first substrate, a plurality of first connection pads over the plurality of first interconnect structures and a plurality of first bonding pads, wherein a first bonding pad is formed over a corresponding first connection pad, and a second chip comprising a plurality of second interconnect structures over a second substrate and a plurality of second bonding pads over the plurality of second interconnect structures, wherein the first chip and the second chip are face-to-face bonded together, and wherein a first bonding pad is in direct contact with a corresponding second bonding pad.

A packaged semiconductor device includes a substrate and a contact pad disposed on the semiconductor substrate. The packaged semiconductor device also includes a dielectric layer disposed over the contact pad, the dielectric layer including a first opening over the contact pad, and an insulator layer disposed over the dielectric layer, the insulator layer including a second opening over the contact pad. The packaged semiconductor device also includes a molding material disposed around the substrate, the dielectric layer, and the insulator layer and a wiring over the insulator layer and extending through the second opening, the wiring being electrically coupled to the contact pad.

A fingerprint sensing device comprising sensing circuitry comprising a plurality of sensing elements, each sensing element comprising a sensing structure arranged in a sensing plane and facing a surface of the capacitive fingerprint sensing device, each of the sensing elements being configured to provide a signal indicative of an electromagnetic coupling between the sensing structure and a finger placed on the surface of the fingerprint sensing device; and a plurality of connection pads electrically connected to the sensing circuitry for providing an electrical connection between the sensing circuitry and readout circuitry, wherein each of the connection pads is separately recessed in relation to the sensing plane such that each connection pad has a floor in a floor plane, and wherein each connection pad is separated from an adjacent connection pad through a portion of the sensing device being elevated in relation to the floor plane.

To improve an integration degree of a semiconductor device. The semiconductor device includes a plurality of wiring layers formed on the semiconductor substrate, a pad electrode formed on an uppermost wiring layer among the plurality of wiring layers, a base insulating film having a pad opening above the pad electrode, and a rewiring electrically connected to the pad electrode and extending over the base insulating film. Further, the semiconductor device includes a protective film covering an upper surface of the rewiring and having an external pad opening exposing part of the upper surface of the rewiring, an external pad electrode electrically connected to the rewiring through the external pad opening and extending over the protective film, and a wire connected to the external pad electrode. Part of the external pad electrode is located in a region outside the rewiring.

Packaged semiconductor devices, methods of packaging semiconductor devices, and package-on-package (PoP) devices are disclosed. In some embodiments, a method of packaging a semiconductor device includes forming through-package vias (TPVs) over a carrier, and coupling a semiconductor device to the carrier. The semiconductor device includes contact pads disposed on a surface thereof and an insulating material disposed over the contact pads. A molding material is formed over the carrier between the TPVs and the semiconductor device. Openings are formed in the insulating material using a laser drilling process over the contact pads, and a redistribution layer (RDL) is formed over the insulating material and the openings in the insulating material. A portion of the RDL is coupled to a top surface of each of the contact pads.

A method for increasing dielectric bonding strength during wafer-level processing is incorporated into a hybrid bonding process. A method may include immersing a substrate into a chemical bath at atmospheric conditions where the chemical bath forms a self-assembled monolayer on metal surfaces of the substrate and selectively depositing a high-k dielectric material to form a dielectric cap on dielectric surfaces of the substrate absent of the self-assembled monolayer.

A first bonding structure is directly bonded to a second bonding structure. The forming of the first structure includes: forming a blocking layer on a metallic material layer including a first portion covering a concaved portion of the metallic material layer and a second portion covering a non-concaved portion of the metallic material layer, performing a first planarization process to remove the second portion of the blocking layer while the first portion of the blocking layer remains, performing a second planarization process to remove the non-concaved portion of the metallic material layer and expose the barrier layer on the insulating layer, and performing a wet etching process to remove the barrier layer on the insulating layer and the blocking layer to form the first bonding pad including the barrier layer in the opening and the metallic material layer.

In some embodiments, the present disclosure relates to a device that includes an interconnect structure arranged on a frontside of a substrate. The interconnect structure includes interconnect conductive structures embedded within interconnect dielectric layers. A trench extends completely through the substrate to expose multiples ones of the interconnect conductive structures. A bond pad structure is arranged on a backside of the substrate and extends through the trench of the substrate to contact the multiple ones of the interconnect conductive structures. A bonding structure is arranged on the backside of the substrate and electrically contacts the bond pad structure.

A Cu.sub.3Sn electrical interconnect and method of making same in an electrical device, such as for hybrid bond 3D-integration of the electrical device with one or more other electrical devices. The method of forming the Cu.sub.3Sn electrical interconnect includes: depositing a Sn layer in the via hole; depositing a Cu layer atop and in contact with the Sn layer; and heating the Sn layer and the Cu layer such that the Sn and Cu layers diffuse together to form a Cu.sub.3Sn interconnect in the via hole. During the heating, a diffusion front between the Sn and Cu layers moves in a direction toward the Cu layer as initially deposited, such that any remaining Cu layer or any voids formed during the diffusion are at an upper region of the formed Cu.sub.3Sn interconnect in the via hole, thereby allowing such voids or remaining material to be easily removed.

A Cu.sub.3Sn electrical interconnect and method of making same in an electrical device, such as for hybrid bond 3D-integration of the electrical device with one or more other electrical devices. The method of forming the Cu.sub.3Sn electrical interconnect includes: depositing a Sn layer in the via hole; depositing a Cu layer atop and in contact with the Sn layer; and heating the Sn layer and the Cu layer such that the Sn and Cu layers diffuse together to form a Cu.sub.3Sn interconnect in the via hole. During the heating, a diffusion front between the Sn and Cu layers moves in a direction toward the Cu layer as initially deposited, such that any remaining Cu layer or any voids formed during the diffusion are at an upper region of the formed Cu.sub.3Sn interconnect in the via hole, thereby allowing such voids or remaining material to be easily removed.