A substrate (1) having a GaN surface (2) is immersed in a catalyst metal solution (4) containing potassium hydroxide and a plating catalyst metal salt while being irradiated with ultraviolet light to deposit a catalyst metal (5) on the GaN surface (2). A metal film (7) is formed on the GaN surface (2) having the catalyst metal (5) deposited thereon by electroless plating.

Structures including III-V compound semiconductor-based devices and silicon-based devices integrated on a semiconductor substrate and methods of forming such structures. The structure includes a substrate having a device layer, a handle substrate, and a buried insulator layer between the handle substrate and the device layer. The structure includes a first semiconductor layer on the device layer in a first device region, and a second semiconductor layer on the device layer in a second device region. The first semiconductor layer contains a III-V compound semiconductor material, and the second semiconductor layer contains silicon. A first device structure includes a gate structure on the first semiconductor layer, and a second device structure includes a doped region in the second semiconductor layer. The doped region and the second semiconductor layer define a p-n junction.

The present disclosure relates to a Gallium Nitride (GaN) power transistor, comprising: a buffer layer; a barrier layer deposited on the buffer layer, wherein a gate region is formed on top of the barrier layer; a p-type doped GaN layer deposited on the barrier layer at the gate region; and a metal gate layer deposited on top of the p-type doped GaN layer, wherein the metal gate layer is contacting the p-type doped GaN layer to form a Schottky barrier, wherein a thickness of the p-type doped GaN layer, a metal type of the metal gate layer and a p-type doping concentration of the p-type doped GaN layer are based on a known relationship of a pGaN Schottky gate depletion region thickness with respect to a p-type doping concentration and a gate metal type.

An HEMT includes a first III-V compound layer. A second III-V compound layer is disposed on the first III-V compound layer. The composition of the first III-V compound layer is different from that of the second III-V compound layer. A gate is disposed on the second III-V compound layer. The gate includes a first P-type III-V compound layer, an undoped III-V compound layer and an N-type III-V compound layer are deposited from bottom to top. The first P-type III-V compound layer, the undoped III-V compound layer, the N-type III-V compound layer and the first III-V compound layer are chemical compounds formed by the same group III element and the same group V element. A drain electrode is disposed at one side of the gate. A drain electrode is disposed at another side of the gate. A gate electrode is disposed directly on the gate.

A field effect transistor includes: a semiconductor region including a first inactive region, an active region, and a second inactive region arranged side by side in a first direction; a gate electrode, a source electrode, and a drain electrode on the active region; a gate pad on the first inactive region; a gate guard on and in contact with the semiconductor region, the gate guard being apart from the gate pad and located between an edge on the first inactive region side of the semiconductor region and the gate pad; a drain pad on the second inactive region; a drain guard on and in contact with the semiconductor region, the drain guard being apart from the drain pad and located between an edge on the second inactive region side of the semiconductor region and the drain pad; and a metal film electrically connected to the gate guard.

Provided are a high electron mobility transistor and a method of manufacturing the high electron mobility transistor. The high electron mobility transistor includes a gate electrode provided on a depletion forming layer. The gate electrode includes a first gate electrode configured to form an ohmic contact with the depletion forming layer, and a second gate electrode configured to form a Schottky contact with the depletion forming layer.

Gallium nitride-based monolithic microwave integrated circuits (MMICs) can comprise aluminum-based metals. Electrical contacts for gates, sources, and drains of transistors can include aluminum-containing metallic materials. Additionally, connectors, inductors, and interconnect devices can also comprise aluminum-based metals. The gallium-based MMICs can be manufactured in complementary metal oxide semiconductor (CMOS) facilities with equipment that produces silicon-based semiconductor devices.

A device including a substrate, a passivation layer, a source, a gate, a drain, and the gate including at least one step portion. Where the at least one step portion is arranged within the passivation layer, the at least one step portion includes at least one first surface and at least one second surface, where the at least one first surface is connected to the at least one second surface, where the gate includes a third surface, and where the at least one step portion is connected to the third surface. A process is also disclosed.

There is provided a nitride semiconductor device that includes a first nitride semiconductor layer configured as an electron transit layer, a second nitride semiconductor layer formed on the first nitride semiconductor layer and configured as an electron supply layer, a ridge-shaped nitride semiconductor gate layer disposed on the second nitride semiconductor layer and including an acceptor-type impurity, and a gate electrode formed on the nitride semiconductor gate layer. The gate electrode includes a first metal film that is formed on the nitride semiconductor gate layer and is mainly made of Ti, and a second metal film that is formed on the first metal film and is made of TiN.

An HEMT includes a semiconductor body, which includes a semiconductor heterostructure, and a conductive gate region. The gate region includes: a contact region, which is made of a first metal material and contacts the semiconductor body to form a Schottky junction; a barrier region, which is made of a second metal material and is set on the contact region; and a top region, which extends on the barrier region and is made of a third metal material, which has a resistivity lower than the resistivity of the first metal material. The HEMT moreover comprises a dielectric region, which includes at least one front dielectric subregion, which extends over the contact region, delimiting a front opening that gives out onto the contact region; and wherein the barrier region extends into the front opening and over at least part of the front dielectric subregion.