A method includes forming a first substrate including a first dielectric layer and a first metal pad, forming a second substrate including a second dielectric layer and a second metal pad, and bonding the first dielectric layer to the second dielectric layer, and the first metal pad to the second metal pad. One or both of the first and second substrates is formed by forming a first insulating layer, forming an opening in the layer, forming a barrier on an inner surface of the opening, forming a metal pad material on the barrier, polishing the metal pad material to expose a portion of the barrier and to form a gap, expanding the gap, forming a second insulating layer to fill the opening and the gap, and polishing the insulating layers such that a top surface of the metal pad is substantially planar with an upper surface of the polished layer.

A semiconductor device includes a first plurality of dies encapsulated by an encapsulant, an interposer over the first plurality of dies, an interconnect structure over and electrically connected to the interposer, and a plurality of conductive pads on a surface of the interconnect structure opposite the interposer. The interposer includes a plurality of embedded passive components. Each die of the first plurality of dies is electrically connected to the interposer. The interconnect structure includes a solenoid inductor in a metallization layer of the interconnect structure.

Provided are a solid-state image-capturing device, a semiconductor apparatus, an electronic apparatus, and a manufacturing method that enable improvement in reliability of through electrodes and increase in density of through electrodes. A common opening portion is formed including a through electrode formation region that is a region in which the plurality of through electrodes electrically connected respectively to a plurality of electrode pads provided on a joint surface side from a device formation surface of a semiconductor substrate is formed. A plurality of through portions is formed so as to penetrate to the plurality of respective electrode pads in the common opening portion, and wiring is formed along the common opening portion and the through portions from the electrode pads to the device formation surface corresponding to the respective through electrodes. The present technology can be applied to a layer-type solid-state image-capturing device, for example.

Provided are a solid-state image-capturing device, a semiconductor apparatus, an electronic apparatus, and a manufacturing method that enable improvement in reliability of through electrodes and increase in density of through electrodes. A common opening portion is formed including a through electrode formation region that is a region in which the plurality of through electrodes electrically connected respectively to a plurality of electrode pads provided on a joint surface side from a device formation surface of a semiconductor substrate is formed. A plurality of through portions is formed so as to penetrate to the plurality of respective electrode pads in the common opening portion, and wiring is formed along the common opening portion and the through portions from the electrode pads to the device formation surface corresponding to the respective through electrodes. The present technology can be applied to a layer-type solid-state image-capturing device, for example.

Embodiments of the present disclosure relate to methods of fabricating IC devices with IC structures with improved bonding between a semiconductor layer and a non-semiconductor support structure, as well as resulting IC devices, assemblies, and systems. An example method includes providing a semiconductor material over a semiconductor support structure and, subsequently, depositing a first bonding material on the semiconductor material. The method further includes depositing a second bonding material on a non-semiconductor support structure such as glass or mica wafers, followed by bonding the face of the semiconductor material with the first bonding material to the face of the non-semiconductor support structure with the second bonding material. Using first and second bonding materials that include silicon, nitrogen, and oxygen (e.g., silicon oxynitride or carbon-doped silicon oxynitride) may significantly improve bonding between semiconductor layers and non-semiconductor support structures compared to layer transfer techniques.

Layer structures for making direct metal-to-metal bonds at low temperatures and shorter annealing durations in microelectronics are provided. Example bonding interface structures enable direct metal-to-metal bonding of interconnects at low annealing temperatures of 150° C. or below, and at a lower energy budget. The example structures provide a precise metal recess distance for conductive pads and vias being bonded that can be achieved in high volume manufacturing. The example structures provide a vertical stack of conductive layers under the bonding interface, with geometries and thermal expansion features designed to vertically expand the stack at lower temperatures over the precise recess distance to make the direct metal-to-metal bonds. Further enhancements, such as surface nanotexture and copper crystal plane selection, can further actuate the direct metal-to-metal bonding at lowered annealing temperatures and shorter annealing durations.

The present description relates to a method of manufacturing an electronic circuit (30) comprising: a support (32), an assembly site (31) having a first surface protruding from said support intended to be assembled to an assembly site of another electronic circuit by a self-assembly method; and a peripheral area (39) around said assembly site, the assembly site (31) comprising at least one level, each level comprising conductive pads (34) and insulating posts (380) between the conductive pads, said manufacturing method comprising the forming of said at least one level of the assembly site, such that the edges, in at least one direction (X) of the main plane (XY), of each level of the assembly site and the locations, in the at least one direction (X), of the conductive pads and of the insulating posts of the same level are defined in a same photolithography step of said method.

A semiconductor device includes a first layer including a plurality of first pads, and a second layer including a plurality of second pads. The plurality of first pads are bonded to the plurality of second pads, respectively. At least one of the first pads or the second pads continuously surrounds an insulating portion.

A semiconductor device includes a first semiconductor chip that includes a first conductive pad whose top surface is exposed; and a second semiconductor chip that includes a second conductive pad whose top surface is exposed and in contact with at least a portion of the top surface of the first conductive pad. The first semiconductor chip may include a first diffusion barrier in contact with a bottom surface of the first conductive pad, and a second diffusion barrier in contact with a lateral surface of the first conductive pad, and the first diffusion barrier and the second diffusion barrier may include different materials from each other.

A method for fabricating a semiconductor product includes forming a dielectric layer over a top level metallization layer of a semiconductor process wafer. The dielectric layer is patterned using a grayscale mask process to define a contact pad opening in the dielectric layer, thereby producing a patterned dielectric layer in which the contact pad opening is aligned to a contact pad defined in the top level metallization layer. A metal layer is deposited over the patterned dielectric layer, including within the contact pad opening. A portion of the metal layer is removed by a chemical mechanical polishing (CMP) process, with a remaining portion of the metal layer having a sloped sidewall.