Abstract: An electronic device may have a display. The display may include an array of pixels formed on a silicon substrate. Display driver circuitry may be formed in a display driver integrated circuit that outputs display data and other control signals for operating the display. An interposer structure may be included in the electronic device. The interposer structure may be attached to the silicon display substrate and may only partially overlap the silicon display substrate. The display driver integrated circuit may be attached to the interposer structure and provide signals to the display pixels through the interposer structure. In another possible arrangement, the display driver integrated circuit may bridge a gap between the silicon display substrate and the flexible printed circuit. The display driver integrated circuit only partially overlaps the silicon display substrate in this arrangement.

Abstract: A multi-gate high electron mobility transistor (HEMT) and its methods of formation are disclosed. The multi-gate HEMT includes a substrate and an adhesion layer on top of the substrate. A channel layer is disposed on top of the adhesion layer, and a first gate electrode is disposed on top of the channel layer. The first gate electrode has a first gate dielectric layer in between the first gate electrode and the channel layer. A second gate electrode is embedded within the substrate and beneath the channel layer. The second gate electrode has a second gate dielectric layer completely surrounding the second gate electrode. A pair of source and drain contacts are disposed on opposite sides of the first gate electrode.

Abstract: A method including forming a barrier layer on a polar compound semiconductor layer on a sacrificial substrate; coupling the sacrificial substrate to a carrier substrate to form a composite structure wherein the barrier layer is disposed between the polar compound semiconductor layer and the carrier substrate; separating the sacrificial substrate from the composite structure to expose the polar compound semiconductor layer; and forming at least one circuit device. An apparatus including a barrier layer on a substrate; a transistor device on the barrier layer; and a polar compound semiconductor layer disposed between the barrier layer and the transistor device, the polar compound semiconductor layer including a two-dimensional electron gas therein.

Abstract: A multi-gate high electron mobility transistor (HEMT) and its methods of formation are disclosed. The multi-gate HEMT includes a substrate and an adhesion layer on top of the substrate. A channel layer is disposed on top of the adhesion layer, and a first gate electrode is disposed on top of the channel layer. The first gate electrode has a first gate dielectric layer in between the first gate electrode and the channel layer. A second gate electrode is embedded within the substrate and beneath the channel layer. The second gate electrode has a second gate dielectric layer completely surrounding the second gate electrode. A pair of source and drain contacts are disposed on opposite sides of the first gate electrode.

Abstract: A method including forming a barrier layer on a polar compound semiconductor layer on a sacrificial substrate; coupling the sacrificial substrate to a carrier substrate to form a composite structure wherein the barrier layer is disposed between the polar compound semiconductor layer and the carrier substrate; separating the sacrificial substrate from the composite structure to expose the polar compound semiconductor layer; and forming at least one circuit device. An apparatus including a barrier layer on a substrate; a transistor device on the barrier layer; and a polar compound semiconductor layer disposed between the barrier layer and the transistor device, the polar compound semiconductor layer including a two-dimensional electron gas therein.

Abstract: Techniques are disclosed for heteroepitaxial growth of a layer of lattice-mismatched semiconductor material on an initial substrate, and transfer of a defect-free portion of that layer to a handle wafer or other suitable substrate for integration. In accordance with some embodiments, transfer may result in the presence of island-like oxide structures on the handle wafer/substrate, each having a defect-free island of the lattice-mismatched semiconductor material embedded within its upper surface. Each defect-free semiconductor island may have one or more crystalline faceted edges and, with its accompanying oxide structure, may provide a planar surface for integration. In some cases, a layer of a second, different semiconductor material may be heteroepitaxially grown over the handle wafer/substrate to fill areas around the transferred islands. In some other cases, the handle wafer/substrate itself may be homoepitaxially grown to fill areas around the transferred islands.

Abstract: Techniques are disclosed for heteroepitaxial growth of a layer of lattice-mismatched semiconductor material on an initial substrate, and transfer of a defect-free portion of that layer to a handle wafer or other suitable substrate for integration. In accordance with some embodiments, transfer may result in the presence of island-like oxide structures on the handle wafer/substrate, each having a defect-free island of the lattice-mismatched semiconductor material embedded within its upper surface. Each defect-free semiconductor island may have one or more crystalline faceted edges and, with its accompanying oxide structure, may provide a planar surface for integration. In some cases, a layer of a second, different semiconductor material may be heteroepitaxially grown over the handle wafer/substrate to fill areas around the transferred islands. In some other cases, the handle wafer/substrate itself may be homoepitaxially grown to fill areas around the transferred islands.

Abstract: Techniques are disclosed for heteroepitaxial growth of a layer of lattice-mismatched semiconductor material on an initial substrate, and transfer of a defect-free portion of that layer to a handle wafer or other suitable substrate for integration. In accordance with some embodiments, transfer may result in the presence of island-like oxide structures on the handle wafer/substrate, each having a defect-free island of the lattice-mismatched semiconductor material embedded within its upper surface. Each defect-free semiconductor island may have one or more crystalline faceted edges and, with its accompanying oxide structure, may provide a planar surface for integration. In some cases, a layer of a second, different semiconductor material may be heteroepitaxially grown over the handle wafer/substrate to fill areas around the transferred islands. In some other cases, the handle wafer/substrate itself may be homoepitaxially grown to fill areas around the transferred islands.

Abstract: Techniques are disclosed for heteroepitaxial growth of a layer of lattice-mismatched semiconductor material on an initial substrate, and transfer of a defect-free portion of that layer to a handle wafer or other suitable substrate for integration. In accordance with some embodiments, transfer may result in the presence of island-like oxide structures on the handle wafer/substrate, each having a defect-free island of the lattice-mismatched semiconductor material embedded within its upper surface. Each defect-free semiconductor island may have one or more crystalline faceted edges and, with its accompanying oxide structure, may provide a planar surface for integration. In some cases, a layer of a second, different semiconductor material may be heteroepitaxially grown over the handle wafer/substrate to fill areas around the transferred islands. In some other cases, the handle wafer/substrate itself may be homoepitaxially grown to fill areas around the transferred islands.

Abstract: A new composition of matter is described, amorphous GaN1-xAsx:Mg, wherein 0<x<1, and more preferably 0.1<x<0.8, which amorphous material is of low resistivity, and when formed as a thin, heavily doped film may be used as a low resistant p-type ohmic contact layer for a p-type group III-nitride layer in such applications as photovoltaic cells. The layer may be applied either as a conformal film or a patterned layer. In one embodiment, as a lightly doped but thicker layer, the amorphous GaN1-xAsx:Mg film can itself be used as an absorber layer in PV applications. Also described herein is a novel, low temperature method for the formation of the heavily doped amorphous GaN1-xAsx:Mg compositions of the invention in which the doping is achieved during film formation according to MBE methods.