A bonded assembly includes a first semiconductor die that includes first metallic bonding structures embedded within a first bonding-level dielectric layer, and a second semiconductor die that includes second metallic bonding structures embedded within a second bonding-level dielectric layer and bonded to the first metallic bonding structures by metal-to-metal bonding. One of the first metallic bonding structures a pad portion, and a via portion located between the pad portion and the first semiconductor device, the via portion having second tapered sidewalls.

According to embodiments, a semiconductor device is provided. The semiconductor device includes an insulation layer, an electrode, and a groove. The insulation layer is provided on a surface of a substrate. The electrode is buried in the insulation layer, and a first end surface of the electrode is exposed from the insulation layer. The groove is formed around the electrode on the surface of the substrate. The groove has an outside surface of the electrode as one side surface, and the groove is opened on the surface side of the insulation layer. The first end surface of the electrode buried in the insulation layer protrudes from the surface of the insulation layer.

A semiconductor package and a method for manufacturing a semiconductor package are provided. The semiconductor package includes a first semiconductor device, a second semiconductor device, and an alignment material. The first semiconductor device has a first bonding layer, and the first bonding layer includes a first bond pad contacting an organic dielectric material. The second semiconductor device has a second bonding layer, and the second bonding layer includes a second bond pad contacting the organic dielectric material. The alignment material is between the first bonding layer and the second bonding layer.

Embodiments of the present disclosure propose a semiconductor packaging method and a semiconductor structure. The semiconductor packaging method includes: providing a substrate; forming a metal pad on the substrate, where there is a gap between a sidewall of the metal pad and the substrate; and connecting multiple metal pads on substrates to each other.

A semiconductor package includes: a semiconductor chip including a chip pad on a first surface; a first insulating layer arranged on the semiconductor chip and including an insulating hole exposing the chip pad; a redistribution pattern including a redistribution via pattern arranged on an internal surface of the first insulating layer configured to define the first insulating hole and on a surface of the chip pad, and a redistribution line pattern arranged on a surface of the first insulating layer; an under bump metal (UBM) conformally arranged along a surface of the redistribution pattern; and a connection terminal arranged on the UBM, wherein the redistribution line pattern and the UBM provide a dummy space of a shape protruding in a direction toward the first surface of the semiconductor chip, and a portion of the connection terminal fills the dummy space.

A bonding method and a bonding structure are provided. A device substrate is provided including a plurality of semiconductor devices, wherein each of the semiconductor devices includes a first bonding layer. A cap substrate is provided including a plurality of cap structures, wherein each of the cap structures includes a second bonding layer, the second bonding layer having a planar surface and a first protrusion protruding from the planar surface. The device substrate is bonded to the cap substrate by engaging the first protrusion of the second bonding layer of each of the cap structures with the corresponding first bonding layer of each of the semiconductor devices in the device substrate.

A method of bonding includes using a bonding layer having a fluorinated oxide. Fluorine may be introduced into the bonding layer by exposure to a fluorine-containing solution, vapor or gas or by implantation. The bonding layer may also be formed using a method where fluorine is introduced into the layer during its formation. The surface of the bonding layer is terminated with a desired species, preferably an NH.sub.2 species. This may be accomplished by exposing the bonding layer to an NH.sub.4OH solution. High bonding strength is obtained at room temperature. The method may also include bonding two bonding layers together and creating a fluorine distribution having a peak in the vicinity of the interface between the bonding layers. One of the bonding layers may include two oxide layers formed on each other. The fluorine concentration may also have a second peak at the interface between the two oxide layers.

Representative techniques and devices, including process steps may be employed to mitigate undesired dishing in conductive interconnect structures and erosion of dielectric bonding surfaces. For example, an embedded layer may be added to the dished or eroded surface to eliminate unwanted dishing or voids and to form a planar bonding surface. Additional techniques and devices, including process steps may be employed to form desired openings in conductive interconnect structures, where the openings can have a predetermined or desired volume relative to the volume of conductive material of the interconnect structures. Each of these techniques, devices, and processes can provide for the use of larger diameter, larger volume, or mixed-sized conductive interconnect structures at the bonding surface of bonded dies and wafers.

A semiconductor device includes two integrated circuit (IC) chips. The first IC chip includes substrate, a spacer connected to the substrate and including holes, wherein at least one of the holes has a first shape, and solder bumps positioned in the holes, respectively. The second IC chip includes a substrate, electrode pads extending from the substrate and connected to the solder bumps, respectively. At least one of the electrode pads that corresponds to the at least one of the solder bumps has a second shape, and the first shape and the second shape are non-coextensive such that there is at least one gap between the first shape and the second shape when projected on each other.

Representative techniques and devices, including process steps may be employed to mitigate undesired dishing in conductive interconnect structures and erosion of dielectric bonding surfaces. For example, an embedded layer may be added to the dished or eroded surface to eliminate unwanted dishing or voids and to form a planar bonding surface. Additional techniques and devices, including process steps may be employed to form desired openings in conductive interconnect structures, where the openings can have a predetermined or desired volume relative to the volume of conductive material of the interconnect structures. Each of these techniques, devices, and processes can provide for the use of larger diameter, larger volume, or mixed-sized conductive interconnect structures at the bonding surface of bonded dies and wafers.