Embodiments of the disclosure provide an electrically programmable fuse (efuse) over crystalline semiconductor material. A structure according to the disclosure includes a plurality of crystalline semiconductor layers. Each crystalline semiconductor layer includes a compound material. A metallic layer is on the plurality of crystalline semiconductor layers. The metallic layer has a lower resistivity than an uppermost layer of the plurality of crystalline semiconductor layers. A pair of gate conductors is on respective portions of the metallic layer. The metallic layer defines an electrically programmable fuse (efuse) link between the gate conductors.

Semiconductor structures with reduced parasitic capacitance between interconnects and ground, for example, are described. In one case, a semiconductor structure includes a substrate and a low dielectric constant material region in the substrate. The low dielectric constant material region is positioned between a first device area in the semiconductor structure and a second device area in the semiconductor structure. The semiconductor structure also includes a III-nitride material layer over the substrate. The III-nitride material layer extends over the substrate in the first device area, over the low dielectric constant material region, and over the substrate in the second device area. The semiconductor structure can also include a first device formed in the III-nitride material layer in the first device area, a second device in the III-nitride material layer in the second device area, and an interconnect formed over the low dielectric constant material region. The interconnect can provide a continuous conductive path of metal from the first device area, over the low dielectric constant material region, and to the second device area.

An apparatus includes a substrate; a group III-Nitride barrier layer; a source electrically coupled to the group III-Nitride barrier layer; a gate on the group III-Nitride barrier layer; a drain electrically coupled to the group III-Nitride barrier layer; a p-region being arranged at or below the group III-Nitride barrier layer; and a recovery enhancement circuit configured to reduce an impact of an overload received by the gate. Additionally, at least a portion of the p-region is arranged vertically below at least one of the following: the source, the gate, an area between the gate and the drain.

A nitride semiconductor substrate, including a Ga-containing nitride semiconductor thin film formed on a substrate for film-forming in which a single crystal silicon layer is formed above a supporting substrate via an insulative layer, wherein the nitride semiconductor substrate has a region where the Ga-containing nitride semiconductor thin film is not formed inward from an edge of the single crystal silicon layer being a growth surface of the nitride semiconductor thin film. This provides: a nitride semiconductor substrate with inhibited generation of a reaction mark; and a manufacturing method therefor.

A nitride-based semiconductor integrated circuit (IC) chip is provided. The IC chip comprises: a substrate; intra-transistor isolation regions formed in a surface of the substrate for defining power domains respectively for transistors integrated in the IC chip; an epitaxial body layer disposed over the substrate and the intra-transistor isolation regions; a first and a second nitride-based layers disposed above the epitaxial body layer. The epitaxial body layer and the substrate are formed of a same material and each of the one or more intra-transistor isolation regions is implanted to have a doping polarity opposite to a doping polarity of the substrate. By the implementation of the epitaxial body layer over the isolation regions, the quality of the heterojunction formed between the nitride-based semiconductor layers can be guaranteed as the impact of implantation of the isolation regions to the formation of heterojunction interface can be eliminated.

A method for making a semiconductor structure includes defining one or more device areas and one or more interconnect areas on a silicon substrate, forming trenches in the interconnect areas of the silicon substrate, oxidizing the silicon substrate in the trenches to form silicon dioxide regions, forming a III-nitride material layer on the surface of the silicon substrate, forming devices in the device areas of the gallium nitride layer, and forming interconnects in the interconnect areas. The silicon dioxide regions reduce parasitic capacitance between the interconnects and ground.

According to an aspect of the present disclosure, there is provided a III-N semiconductor structure comprising: a semiconductor-on-insulator substrate; a buffer structure comprising a superlattice including at least a first superlattice block and a second superlattice block formed on the first superlattice block, the first superlattice block including a repetitive sequence of first superlattice units, each first superlattice unit including a stack of layers of AlGaN, wherein adjacent layers of the stack have different aluminum content, the second superlattice block including a repetitive sequence of second superlattice units, each second superlattice unit including a stack of layers of AlGaN, wherein adjacent layers of the stack have different aluminum content, wherein an average aluminum content of the second superlattice block is greater than an average aluminum content of the first superlattice block; and a III-N semiconductor channel layer arranged on the buffer structure.

A method of fabricating an electronic device includes providing a III-V substrate having a hexagonal crystal structure and a normal to a growth surface characterized by a misorientation from the <0001> direction of between 0.15? and 0.65?. The method also includes growing a first III-V epitaxial layer coupled to the III-V substrate and growing a second III-V epitaxial layer coupled to the first III-V epitaxial layer. The method further includes forming a first contact in electrical contact with the III-V substrate and forming a second contact in electrical contact with the second III-V epitaxial layer.

A semiconductor structure includes a substrate, a first III-V compound layer, a second III-V compound layer, a third III-V compound layer, and a fourth III-V compound layer. The top of the substrate includes a first region and a second region. The first III-V compound layer is in the first region. The second III-V compound layer is disposed over the first III-V compound layer. A first carrier channel is formed between the first III-V compound layer and the second III-V compound layer. The second III-V compound layer has a first thickness. The third III-V compound layer is in the second region. The fourth III-V compound layer is disposed over the third III-V compound layer. A second carrier channel is formed between the fourth III-V compound layer and the third III-V compound layer. The fourth III-V compound layer has a second thickness less than the first thickness.

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; a first interlayer insulating layer formed over the first source electrode and the second source electrode; and a second interlayer insulating layer formed in the first separation trench.