A display device including: a substrate including pixel electrodes; a passivation layer on the substrate, a groove in the passivation layer between the pixel electrodes;

contact electrodes on the pixel electrodes; and a light-emitting element layer comprising a plurality of light-emitting elements respectively bonded onto the contact electrodes and having a plurality of semiconductor layers thereon. The groove does not overlap the plurality of light-emitting elements.

Provided is a semiconductor device capable of suppressing an Al slide at a time of an operation under a high temperature in a laminated structure of an aluminum electrode layer and a copper electrode layer. Accordingly, in the semiconductor device according to the present disclosure, a first copper electrode layer includes a plurality of protruding regions as regions protruding toward the aluminum electrode layer in an interface with the aluminum electrode layer.

A semiconductor device includes a substrate, a conductive part, a controller module and a sealing resin. The substrate has a substrate obverse surface and a substrate reverse surface facing away from each other in a z direction. The conductive part is made of an electrically conductive material on the substrate obverse surface. The controller module is disposed on the substrate obverse surface and electrically connected to the conductive part. The sealing resin covers the controller module and at least a portion of the substrate. The conductive part includes an overlapping wiring trace having an overlapping portion overlapping with the electronic component as viewed in the z direction. The overlapping portion of the overlapping wiring trace is not electrically bonded to the controller module.

In this semiconductor device, an emitter electrode of a power semiconductor element includes a first sub-electrode provided in a region including a central portion of a front surface of a semiconductor substrate and a second sub-electrode provided in a region not including the central portion of the front surface of the semiconductor substrate. A first bonding wire connects the first sub-electrode and an emitter terminal. A second bonding wire connects the second sub-electrode and the emitter terminal. First and second voltage detectors detect voltages between the emitter terminal and the first and second sub-electrodes, respectively. It is possible to separately detect degradation of both the first bonding wire that degrades in an early period and the second bonding wire that degrades in a terminal period.

A light-emitting device includes a substrate and an epitaxial unit. The substrate has a first and a second surface. The substrate is formed on the first surface with a plurality of protrusions. The epitaxial unit includes a first semiconductor layer, an active layer, and a second semiconductor layer that are sequentially disposed on the first surface of the substrate. The first surface of the substrate has a first area that is not covered by the epitaxial unit, and a second area this is covered by the epitaxial unit. A height difference (h2) between the first area and the second area is no greater than 1 μm. A display apparatus and a lighting apparatus are also disclosed.

Substrates that are bonding targets are bonded in ambient atmosphere via bonding films, including oxides, formed on bonding faces of the substrates. The bonding films, which are metal or semiconductor thin films formed by vacuum film deposition and at least the surfaces of which are oxidized, are formed into the respective smooth faces of two substrates having the smooth faces that serve as the bonding faces. The bonding films are exposed to a space that contains moisture, and the two substrates are overlapped in the ambient atmosphere such that the surfaces of the bonding films are made to be hydrophilic and the surfaces of the bonding films contact one another. Through this, a chemical bond is generated at the bonded interface, and thereby the two substrates are bonded together in the ambient atmosphere. The bonding strength γ can be improved by heating the bonded substrates at a temperature.

Bond pads for semiconductor die assemblies, and associated methods and systems are disclosed. In one embodiment, a semiconductor die assembly includes a first semiconductor die including a first bond pad on a first side of the first semiconductor die. The semiconductor die assembly further includes a second semiconductor die including a second bond pad on a second side of the second semiconductor die. The first bond pad is aligned and bonded to the second bond pad at a bonding interface between the first and second bond pads, and at least one of the first and second bond pads include a first metal and a second metal different than the first metal. Further, the first metal is located at the bonding interface and the second metal has a first thickness corresponding to at least one-fourth of a second thickness of the first or second bond pad.

A semiconductor device and method of manufacturing the same are provided. The semiconductor device may include a substrate, a first via, a first pad, a second pad, and a first passivation layer. The first pad may be over the substrate. The second pad may be over the substrate. The second pad may be parallel to the first pad. The first passivation layer may surround the first pad and the second pad. The first passivation layer may include a first part on the first pad. The first passivation layer may include a second part on the second pad. A thickness of the first part of the first passivation layer may exceed a height of the first pad. A thickness of the second part of the first passivation layer may exceed a height of the second pad.

A display device includes a substrate, a first light-emitting element, a second light-emitting element, and a third light-emitting element on the substrate, each of the first, second, and third light-emitting elements includes a first semiconductor layer, an active layer, a second semiconductor layer, and a third semiconductor layer, an opening formed in the second semiconductor layer and the third semiconductor layer of the third light-emitting element, and a wavelength conversion member located at the opening, wherein the first light-emitting element and the third light-emitting element are configured to emit first light, and the second light-emitting element is configured to emit second light, and the wavelength conversion member is configured to convert the first light from the third light-emitting element into third light.

A chip structure is provided. The chip structure includes a substrate. The chip structure includes an interconnect structure over the substrate. The chip structure includes a conductive pad over the interconnect structure. The chip structure includes a passivation layer covering the interconnect structure and exposing the conductive pad. The chip structure includes a first etch stop layer over the passivation layer. The chip structure includes a first buffer layer over the first etch stop layer. The chip structure includes a second etch stop layer over the first buffer layer. The chip structure includes a device element over the second etch stop layer.