A method of manufacturing a semiconductor element according to the present disclosure includes an element forming step (S1) of forming, on an underlying substrate (11), a semiconductor element (15) connected to the underlying substrate (11) via a connecting portion (13b) and including an upper surface (15a) inclined with respect to a growth surface of the underlying substrate (11), a preparing step (S2) of preparing a support substrate (16) including an opposing surface (16c) facing the underlying substrate (11), a bonding step (S3) of pressing the upper surface (15a) of the semiconductor element (15) against the opposing surface (16c) of the support substrate (16) and heating the upper surface (15a) to bond the upper surface (15a) of the semiconductor element (15) to the support substrate (16), and a peeling step (S4) of peeling the semiconductor element (15) from the underlying substrate (11).

A method for forming a direct hybrid bond and a device resulting from a direct hybrid bond including a first substrate having a first set of metallic bonding pads, preferably connected to a device or circuit, capped by a conductive barrier, and having a first non-metallic region adjacent to the metallic bonding pads on the first substrate, a second substrate having a second set of metallic bonding pads capped by a second conductive barrier, aligned with the first set of metallic bonding pads, preferably connected to a device or circuit, and having a second non-metallic region adjacent to the metallic bonding pads on the second substrate, and a contact-bonded interface between the first and second set of metallic bonding pads capped by conductive barriers formed by contact bonding of the first non-metallic region to the second non-metallic region.

Electronic packages and electronic systems are described in which a package redistribution layer of the electronic package includes structural features such a via line connections to reduce stress concentration, particularly when the package redistribution layer is formed of organic dielectric materials.

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.

A first semiconductor device includes: a first wiring layer including a first interlayer insulating film, a first electrode pad, and a first dummy electrode, the first electrode pad being embedded in the first interlayer insulating film and having one surface located on same plane as one surface of the first interlayer insulating film, and the first dummy electrode being embedded in the first interlayer insulating film, having one surface located on same plane as the one surface of the first interlayer insulating film, and being disposed around the first electrode pad; and a second wiring layer including a second interlayer insulating film, a second electrode pad, and a second dummy electrode, the second electrode pad being embedded in the second interlayer insulating film, having one surface located on same surface as one surface of the second interlayer insulating film, and being bonded to the first electrode pad, and the second dummy electrode having one surface located on same plane as the surface located closer to the first interlayer insulating film of the second interlayer insulating film, being disposed around the second electrode pad, and being bonded to the first dummy electrode. A second semiconductor device includes: a first semiconductor section including a first electrode, the first electrode being formed on a surface located closer to a bonding interface and extending in a first direction; and a second semiconductor section including a second electrode and disposed to be bonded to the first semiconductor section at the bonding interface, the second electrode being bonded to the first electrode and extending in a second direction that intersects with the first direction.

A package includes first package component and a second package component. The first package component includes a first electrical connector at a surface of the first package component, and a first solder region on a surface of the first electrical connector. The second package component includes a second electrical connector at a surface of the second package component, and a second solder region on a surface of the second electrical connector. A metal pin has a first end bonded to the first solder region, and a second end bonded to the second solder region.

The present disclosure relates to a semiconductor device and an electronic apparatus which is capable of reducing variations and deterioration of transistor characteristics. A first connection pad connected with a first wiring and a first floating metal greater than the first connection pad are formed at a bonding surface of a first substrate, whereas a second connection pad connected with a second wiring and a second floating metal greater than the second connection pad are formed at a bonding surface of a second substrate. The, and the first floating metal and the second floating metal formed at the first substrate and the second substrate are bonded to each other. The present disclosure is applicable to a CMOS solid-state imaging device used for an imaging apparatus such as a camera, for example.

A display device includes a plate-like substrate having a first surface and a second surface, pixel units on the first surface, and a power supply voltage feeder on the second surface. The power supply voltage feeder outputs first and second power supply voltages applicable to the pixel units. The second power supply voltage is lower in potential than the first power supply voltage. The display device includes a first wiring conductor electrically connecting the power supply voltage feeder and the pixel units and a second wiring conductor electrically connecting the power supply voltage feeder and the pixel units. At least one of the first or second wiring conductor includes a planar conductive portion covering the first surface. The planar conductive portion includes connectors connected to the power supply voltage feeder on at least two sides of the substrate.

Advanced flat metals for microelectronics are provided. While conventional processes create large damascene features that have a dishing defect that causes failure in bonded devices, example systems and methods described herein create large damascene features that are planar. In an implementation, an annealing process creates large grains or large metallic crystals of copper in large damascene cavities, while a thinner layer of copper over the field of a substrate anneals into smaller grains of copper. The large grains of copper in the damascene cavities resist dishing defects during chemical-mechanical planarization (CMP), resulting in very flat damascene features. In an implementation, layers of resist and layers of a second coating material may be applied in various ways to resist dishing during chemical-mechanical planarization (CMP), resulting in very flat damascene features.

The invention provides a semiconductor structure. The semiconductor structure includes a substrate. A first passivation layer is disposed on the substrate. A conductive pad is disposed on the first passivation layer. A second passivation layer is disposed on the first passivation layer. A conductive structure is disposed on the conductive pad, and a passive device is also disposed on the conductive pad, wherein the passive device has a first portion located above the second passivation layer and a second portion passing through the second passivation layer. A solderability preservative film covers the first portion of the passive device, and an under bump metallurgy (UBM) layer covers the second portion of the passive device and a portion of the conductive structure.