Extrinsic structures formed outside the active regions of active devices can influence aging characteristics and performance of the active devices. An example integrated device including such an extrinsic structure includes an active region of a semiconductor device in a plurality of layers of semiconductor materials over a substrate, an isolation region in at least one of the layers of semiconductor materials, the isolation region extending around the semiconductor device in an area outside of the active region, an insulating layer over at least a portion of the active region and over at least a portion of the isolation region, a via in the isolation region and outside the active region, the via extending through the insulating layer and down to a conduction layer among the layers of semiconductor materials in the isolation region, and an interconnect within the via and directly on the conduction layer in the isolation region.

A transistor structure is provided, the transistor structure comprising a source, a drain, and a gate between the source and the drain. The gate may have a top surface. A first field plate may be between the source and the drain. The first field plate may be L-shaped and having a vertical portion over a horizontal portion. A top surface of the vertical portion of the first field plate may be at least as high as the top surface of the gate. A second field plate, whereby the second field plate may be connected to the gate and the second field plate may partially overlap the horizontal portion of the first field plate.

A semiconductor device comprises an insulating region surrounding an active area having a channel direction and a transverse direction that is transverse to the channel direction. A source region and a drain region are disposed in the active area, and are spaced apart along the channel direction. A channel is disposed in the active area and is interposed between the source region and the drain region. The channel comprises a two-dimensional electron gas (2DEG). A gate line is oriented along the transverse direction and is disposed on the channel and has a gate width in the channel direction. The gate line comprises gate material. A gate line terminus is disposed at each end of the gate line. Each gate line terminus comprises the gate material. Each gate line terminus has a width in the channel direction that is at least 1.2 time the gate width.

The present invention provides a nitride semiconductor device, including: a silicon substrate; a first lateral transistor over a first region of the silicon substrate and including: a first nitride semiconductor layer formed over the silicon substrate; and a first gate electrode, a first source electrode and a first drain electrode formed over the first nitride semiconductor layer; a second lateral transistor over a second region of the silicon substrate and including: a second nitride semiconductor layer formed over the silicon substrate; and a second gate electrode, a second source electrode and a second drain electrode formed over the second nitride semiconductor layer; a first separation trench formed over a third region; a source/substrate connecting via hole formed over the third region; and an interlayer insulating layer formed in the first separation trench.

The present invention is directed to III-V semiconductor trench MOSFETs comprising a buried field shield. The invention is further directed to an etch and regrowth method for forming this buried field shield. For example, in III-V trench MOSFETs with an n-type substrate, the region can be formed by an etch into the drift (n-type) and regrowth of p-type semiconductor to form the buried field shield in the trench area and a body/channel outside the trench area. With a narrow trench feature size, the regrowth will planarize enabling subsequent source epitaxy (n-type) without requiring ex-situ processing between body/channel and source growths, eliminating the need for additional masking of the regrowth.

A high-threshold-voltage normally-off high-electron-mobility transistor (HEMT) includes a nucleation layer and an epitaxial layer are grown sequentially on a substrate; a barrier layer, a source, and a drain above the epitaxial layer; the barrier layer and the epitaxial layer form a heterojunction structure, and the contact interface therebetween is induced by polarization charges to generate two-dimensional electron gas. The HEMT includes a passivation layer above the barrier layer; a gate cap layer above the gate region barrier layer; the upper part of the gate cap layer is subjected to surface plasma oxidation to form an oxide dielectric layer, or a single-layer or multiple gate dielectric insertion layer is directly deposited thereon. The HEMT includes a gate is located above the gate dielectric insertion layer; the gate is in contact with the passivation layer; and a field plate extends from the gate to the drain on the passivation layer.

Embodiments of the present invention provide III-V-on-insulator (IIIVOI) platforms for semiconductor devices and methods for fabricating the same. According to one embodiment, compositionally-graded buffer layers of III-V alloy are grown on a silicon substrate, and a smart cut technique is used to cut and transfer one or more layers of III-V alloy to a silicon wafer having an insulator layer such as an oxide. One or more transferred layers of III-V alloy can be etched away to expose a desired transferred layer of III-V alloy, upon which a semi-insulating buffer layer and channel layer can be grown to yield IIIVOI platform on which semiconductor devices (e.g., planar and/or 3-dimensional FETs) can be fabricated.

A nitride-based semiconductor device includes a first nitride-based semiconductor layer, a single III-V group semiconductor layer, a third nitride-based semiconductor layer, a first source electrode and a second electrode, and a gate electrode. The second nitride-based semiconductor layer is disposed over the first nitride-based semiconductor layer. The single III-V group semiconductor layer is disposed between the first and second nitride-based semiconductor layers and doped to the first conductivity type. The single III-V group semiconductor layer has a high resistivity region and a current aperture enclosed by the high resistivity region, in which the high resistivity region comprises more metal oxides than the current aperture so as to achieve a resistivity higher than that of the current aperture. The third nitride-based semiconductor layer is disposed over the second nitride-based semiconductor layer. The first source electrode, the second electrode, and the gate electrode are disposed over the third nitride-based semiconductor layer.

A nitride-based semiconductor device includes a first nitride-based semiconductor layer, a lattice layer, a third nitride-based semiconductor layer, a first source electrode and a second electrode, and a gate electrode. The second nitride-based semiconductor layer is disposed over the first nitride-based semiconductor layer. The lattice layer is disposed between the first and second nitride-based semiconductor layers and doped to the first conductivity type. The lattice layer comprises a plurality of first III-V layers and second III-V layers alternatively stacked. Each of the first III-V layers has a high resistivity region and a current aperture enclosed by the high resistivity region. The high resistivity region comprises more metal oxides than the current aperture. At least two of the current apertures have different dimensions such that interfaces formed between the high resistivity regions and the current apertures misalign with each other. The gate electrode aligns with the current aperture.

A nitride-based semiconductor device includes a first nitride-based semiconductor layer, a lattice layer, a third nitride-based semiconductor layer, a first source electrode and a second electrode, and a gate electrode. The second nitride-based semiconductor layer is disposed over the first nitride-based semiconductor layer. The lattice layer is disposed between the first and second nitride-based semiconductor layers and doped to the first conductivity type. The lattice layer comprises a plurality of first III-V layers and a plurality of second III-V layers alternatively stacked. Each of the first III-V layers has a high resistivity region and a current aperture enclosed by the high resistivity region. The high resistivity region comprises more metal oxides than the current aperture. Interfaces formed between the high resistivity regions and the current apertures among the first III-V layers align with each other. The gate electrode aligns with the current aperture.