A nitride semiconductor device includes a semiconductor carrier, a first nitride-based chip, and first conformal connecting structures. The first nitride-based chip is disposed over the semiconductor carrier. The semiconductor carrier has a first planar surface. The first nitride-based chip has a second planar surface, first conductive pads, and first slanted surfaces. The first conductive pads are disposed in the second planar surface. The first slanted surfaces connect the second planar surface to the first planar surface. The first conformal connecting structures are disposed on the first planar surface and the first nitride-based chip. First obtuse angles are formed between the second planar surface and the first slanted surfaces. Each of the first conformal connecting structures covers one of the first slanted surfaces of the first nitride-based chip and one of the first obtuse angles and is electrically connected to the first conductive pads.

In an embodiment an electronic device includes a carrier board having an upper surface, an electronic chip mounted on the upper surface of the carrier board, the electronic chip having a mounting side facing the upper surface of the carrier board, a flexible mounting layer arranged between the upper surface of the carrier board and the mounting side of the electronic chip, the flexible mounting layer mounting the electronic chip to the carrier board, wherein the mounting side has at least one first region and a second region, and wherein the electronic chip has at least one chip contact element in the first region and at least one connection element arranged on the at least one first region and connecting the at least one chip contact element to the upper surface of the carrier board, wherein the flexible mounting layer separates the second region from the connection element.

Semiconductor devices having electrical interconnections through vertically stacked semiconductor dies, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor assembly includes a die stack having a plurality of semiconductor dies. Each semiconductor die can include surfaces having an insulating material, a recess formed in at least one surface, and a conductive pad within the recess. The semiconductor dies can be directly coupled to each other via the insulating material. The semiconductor assembly can further include an interconnect structure electrically coupled to each of the semiconductor dies. The interconnect structure can include a monolithic via extending continuously through each of the semiconductor dies in the die stack. The interconnect structure can also include a plurality of protrusions extending from the monolithic via. Each protrusion can be positioned within the recess of a respective semiconductor die and can be electrically coupled to the conductive pad within the recess.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

Herein disclosed are a micro-component transfer head, a micro-component transfer device, and a micro-component display. Said micro-component transfer head comprises a carrying surface that corresponds to a micro-component extraction area. Said extraction area conforms with a first geometric object, which comprises at least an acute angle. A second geometric object comprises at least a right angle and is constituted of n copies of the first geometric object, n being an integer greater than 1. The shape of the first geometric object differs from that of the second.

A stack package is disclosed. A first semiconductor die and a supporter are disposed on a package substrate. The supporter may include a second side facing a first side of the first semiconductor die having a substantially inclined surface. A second semiconductor die is stacked on the first semiconductor die and on the supporter. An encapsulant layer is formed to fill a portion between the supporter and the first semiconductor die.

A display device includes a first electrode and a second electrode spaced apart from each other, each of the first electrode and the second electrode including an electrode base layer, a main electrode layer disposed on the electrode base layer, and an electrode upper layer disposed on a portion of the main electrode layer, a first insulating layer disposed on the first electrode and the second electrode, light-emitting elements disposed on the first electrode and the second electrode on the first insulating layer, a first connecting electrode electrically contacting the light-emitting elements, and a second connecting electrode electrically contacting the light-emitting elements. The first electrode includes a first part, the second electrode includes a second part, and the light-emitting elements are disposed on the first part and the second part.

Semiconductor devices, and in particular semiconductor devices for improved resistance measurements and related methods are disclosed. Contact structures for semiconductor devices are disclosed that provide access to resistance measurements with reduced influence of testing-related resistances, thereby improving testing accuracy, particularly for semiconductor devices with low on-resistance ratings. A semiconductor device may include an active region and an inactive region that is arranged along a perimeter of the active region. The semiconductor device may be arranged with a topside contact to provide access for resistance measurements, for example Kelvin-sensing resistance measurements. Related methods include performing resistance measurements from a topside of the semiconductor device, even when the active region of the semiconductor device forms a vertical contact structure.

A device transfer substrate includes a plurality of recesses, wherein each of the plurality of recesses includes a first region having a shape of a first figure, a second region having a shape of a second figure, and an overlapping region formed as a portion of the first region partially overlaps a portion of the second region, wherein a maximum width of the overlapping region in a direction intersecting with a straight line passing through a center of the first figure and a center of the second figure is less than a diameter or a diagonal length of the first figure and less than a diameter or a diagonal length of the second figure.