Embodiments disclosed herein include transistor devices and methods of forming such devices. In an embodiment, a transistor device comprises a channel, where the channel comprises a first semiconductor material. In an embodiment, a source contact is at a first end of the channel, and a drain contact at a second end of the channel. In an embodiment, a gate electrode is between the source contact and the drain contact, and a field plate extends from the gate electrode towards the drain contact. In an embodiment, a plurality of protrusions extend out from the field plate towards the channel, where the protrusions comprise a second semiconductor material

This application provides a chip, a gallium nitride power device, and a power drive circuit. The chip includes a substrate and a plurality of gallium nitride components disposed on the substrate. The plurality of gallium nitride components are arranged in an array. The gallium nitride component includes an active region and a non-active region separately disposed on the substrate. The non-active region surrounds a side surface of the active region. The active region includes a heterojunction formed by a gallium nitride layer and an aluminum gallium nitride layer. The non-active region includes a plurality of grooves spaced apart. The plurality of grooves penetrate the non-active region and expose the substrate, and the plurality of grooves are used to isolate adjacent gallium nitride components.

An integrated circuit structure comprises a base layer that includes a channel region, wherein the base layer and the channel region include group III-V semiconductor material. A polarization layer stack is over the base layer, wherein the polarization layer stack comprises a buffer stack, an interlayer over the buffer stack, a polarization layer over the interlayer. A cap layer stack is over the polarization layer to reduce transistor access resistance.

A field effect transistor, comprising a gate contact and gate metal forming a vertical structure, such vertical structure having sides and a top surrounded by an air gap formed between a source electrode and a drain electrode of the field effect transistor.

The present disclosure relates to semiconductor structures and, more particularly, to a semiconductor device with a dual isolation structure and methods of manufacture. The structure includes: a dual isolation structure including semiconductor material; and an active device region including a channel material and a gate metal material over the channel material. The channel material is between the dual isolation structure and the gate metal material includes a bottom surface not extending beyond a sidewall of the dual isolation structure.

An N-face polar GaN-based device, a composite substrate thereof, and a method of manufacturing the composite substrate are provided in the present disclosure. The N-face polar GaN-based composite substrate includes: a semiconductor substrate, an insulating layer on the semiconductor substrate and a GaN-based material layer on upper surface of the insulating layer; a surface of the GaN-based material layer attached to the insulating layer is Ga-face, and a surface of the GaN-based material layer away from the insulating layer is an N-face. In the present disclosure, the transfer technology is adopted to replace the direct epitaxial growth, which overcomes the difficult growth process, and the N-face polar GaN-based composite substrate with better quality can be obtained.

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 transistor device includes a semiconductor substrate and a gate structure at the upper surface of the substrate. The gate structure is non-planar and includes a metal gate electrode with first and second sidewalls. A first dielectric layer is present over the gate structure. The first dielectric layer includes a first portion that overlies the first sidewall and a second portion that overlies the second sidewall. A portion of a conductive layer over the first dielectric layer forms a field plate with a first portion proximate to the second sidewall of the gate structure. A dielectric sidewall spacer on the first portion of the field plate is formed from a portion of a second dielectric layer, and the dielectric sidewall spacer does not contact the first dielectric layer.

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.

An integrated circuit die includes a quad-gate device nanowire of channel material for a transistor (e.g., single material or stack to be a channel of a MOS device) formed by removing a portion of a sub-fin material from below the channel material, where the sub-fin material was grown in an aspect ration trapping (ART) trench. In some cases, in the formation of such nanowires, it is possible to remove the defective fin material or area under the channel. Such removal isolates the fin channel, removes the fin defects and leakage paths, and forms the nanowire of channel material having four exposed surfaces upon which gate material may be formed.