Electric field management techniques in GaN based semiconductors that utilize patterned regions of differing conductivity under the active GaN device, such as a GaN high electron mobility transistor (HEMT), are described. As an example, a patterned layer of oxidized silicon can be formed superjacent a layer of silicon dioxide during or prior to the heteroepitaxy of GaN or another semiconductor material. These techniques can be useful for back-side electric field management because a silicon layer, for example, can be made conductive to act as a back-side field plate.

Various embodiments of the present disclosure are directed towards a method for forming an image sensor in which a device layer has high crystalline quality. According to some embodiments, a hard mask layer is deposited covering a substrate. A first etch is performed into the hard mask layer and the substrate to form a cavity. A second etch is performed to remove crystalline damage from the first etch and to laterally recess the substrate in the cavity so the hard mask layer overhangs the cavity. A sacrificial layer is formed lining cavity, a blanket ion implantation is performed into the substrate through the sacrificial layer, and the sacrificial layer is removed. An interlayer is epitaxially grown lining the cavity and having a top surface underlying the hard mask layer, and a device layer is epitaxially grown filling the cavity over the interlayer. A photodetector is formed in the device layer.

A semiconductor device include a substrate, a buffer layer formed on the substrate, a channel layer formed by an intrinsic polycrystalline silicon layer on the buffer layer, polycrystalline source and drain by non-intrinsic silicon formed on both sides of the polycrystalline silicon layer, a source electrode and a drain electrode formed on the polycrystalline source and the drain, a gate electrode corresponding to the channel layer, and an NiSi.sub.2 contact layer located between the source and the source electrode and between the drain and the drain electrode.

A vertical semiconductor device may include a semiconductor substrate having at least one trench therein, and a superlattice layer extending vertically adjacent the at least one trench. The superlattice layer may comprise stacked groups of layers, with each group of layers comprising stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer. Each at least one non-semiconductor monolayer of each group of layers may be constrained within a crystal lattice of adjacent base semiconductor portions. The vertical semiconductor device may also include a doped semiconductor layer adjacent the superlattice layer, and a conductive body adjacent the doped semiconductor layer on a side thereof opposite the superlattice layer and defining a vertical semiconductor device contact.

A method for manufacturing an III-nitride semiconductor structure is provided. The method includes providing a substrate comprising a first layer having an upper surface of monocrystalline III-nitride material; providing, over the upper surface, a patterned dielectric layer comprising a first dielectric feature; loading the substrate into a process chamber; exposing the substrate to a first gas mixture comprising at least one Group III-metal organic precursor gas, a nitrogen containing gas and hydrogen gas at a predetermined temperature, thereby forming, on the upper surface, a second layer of a monocrystalline III-nitride material by area selective growth wherein two opposing sidewalls of the dielectric feature are oriented parallel to one of the {11-20} crystal planes of the first layer such that upon formation of the second layer of the monocrystalline III-nitride material, a first trench having tapered sidewalls is formed so that the crystal plane of the second layer parallel to the tapered sidewalls is one of the {1-101} crystal planes.

A method for manufacturing a semiconductor device is provided. The method includes forming at least one epitaxial layer over a substrate; forming a mask over the epitaxial layer; patterning the epitaxial layer into a semiconductor fin; depositing a semiconductor capping layer over the semiconductor fin and the mask, wherein the semiconductor capping layer has a first portion that is amorphous on a sidewall of the mask; performing a thermal treatment such that the first portion of the semiconductor capping layer is converted from amorphous into crystalline; forming an isolation structure around the semiconductor fin; and forming a gate structure over the semiconductor fin.

A method includes providing a semiconductor structure having an active region and an isolation structure adjacent to the active region, the active region having source and drain regions sandwiching a channel region for a transistor, the semiconductor structure further having a gate structure over the channel region. The method further includes etching a trench in one of the source and drain regions, wherein the trench exposes a portion of a sidewall of the isolation structure, epitaxially growing a first semiconductor layer in the trench, epitaxially growing a second semiconductor layer over the first semiconductor layer, changing a crystalline facet orientation of a portion of a top surface of the second semiconductor layer by an etching process, and epitaxially growing a third semiconductor layer over the second semiconductor layer after the changing of the crystalline facet orientation.

Methods and semiconductor structures are provided. A method according to the present disclosure includes forming, over a substrate, a fin-shaped structure that includes a plurality of channel layers interleaved by a plurality of sacrificial layers, recessing a source/drain region of the fin-shaped structure to form a source/drain recess that extends into the substrate and exposes a portion of the substrate, selectively and partially recessing sidewalls of the plurality of sacrificial layers to form inner spacer recesses, forming inner spacers in the inner spacer recesses, selectively forming a buffer semiconductor layer on the exposed portion of the substrate, selectively depositing a first epitaxial layer on sidewalls of the plurality of channel layer and the buffer semiconductor layer such that a top surface of the buffer semiconductor layer is completely covered by the first epitaxial layer, and depositing a second epitaxial layer over the first epitaxial layer and the inner spacers.

A semiconductor-on-insulator substrate for use in RF applications, such as a silicon-on-insulator substrate, comprises a semiconductor top layer, a buried oxide layer and a passivation layer over a support substrate. In addition, a penetration layer is provided between the passivation layer and the silicon support substrate to ensure sufficient high resistivity below RF features and avoid increased migration of dislocations in the support substrate. RF devices may be fabricated on and/or in such a semiconductor-on-insulator substrate.

A semiconductor-on-insulator (e.g., silicon-on-insulator) structure having superior radio frequency device performance, and a method of preparing such a structure, is provided by utilizing a single crystal silicon handle wafer sliced from a float zone grown single crystal silicon ingot.