In an embodiment, a switching circuit is provided that includes a Group III nitride-based semiconductor body including a first monolithically integrated Group III nitride-based transistor device and a second monolithically integrated Group III nitride based transistor device that are coupled to form a half-bridge circuit and are arranged on a common foreign substrate having a common doping level. The switching circuit is configured to operate the half-bridge circuit at a voltage of at least 300 V.

A silicon carbide power device has: a die having a functional layer of silicon carbide and an edge area and an active area, surrounded by the edge area; gate structures formed on a top surface of the functional layer in the active area; and a gate contact pad for biasing the gate structures. The device also has an integrated resistor having a doped region, of a first conductivity type, arranged at the front surface of the functional layer in the edge area; wherein the integrated resistor defines an insulated resistance in the functional layer, interposed between the gate structures and the gate contact pad.

In one embodiment, an integrated circuit die includes a substrate, a base structure, and a plurality of semiconductor structures. The substrate includes silicon. The base structure is above the substrate and includes one or more group III-nitride (III-N) materials. The semiconductor structures are in a two-dimensional (2D) layout on the base structure and include a plurality of metal contacts, at least some of which have different shapes and comprise different metals.

In certain examples, methods and semiconductor structures are directed to a method comprising steps of forming by monolithically integrating or seeding via polycrystalline diamond (PCD) particles on a GaN-based layer characterized as including GaN in at least a surface region of the GaN-based layer. After the step of seeding, the PCD particles are grown under a selected pressure to form a diamond layer section and to provide a semi-conductive structure that includes the diamond layer section integrated on or against the surface region of the GaN-based layer.

A semiconductor device and a method of fabricating the same are proposed. The semiconductor device includes a plurality of hole-channel Group III nitride devices and a plurality of electron-channel Group III nitride devices. In the above, the hole-channel Group III nitride devices and the electron-channel Group III nitride devices are arranged in correspondence with each other. The electron-channel Group III nitride device has a fin-shaped channel, and a two-dimensional hole gas and/or a two-dimensional electron gas can be simultaneously formed at an interface between a compound semiconductor layer and a nitride semiconductor layer.

An integrated circuit structure includes a first semiconductor fin extending horizontally in a length direction and including a bottom portion and a top portion above the bottom portion, a bottom transistor associated with the bottom portion of the first semiconductor fin, a top transistor above the bottom transistor and associated with the top portion of the first semiconductor fin, and a first vertical diode. The first vertical diode includes: a bottom region associated with at least the bottom portion of the first semiconductor fin, the bottom region including one of n-type and p-type dopant; a top region associated with at least the top portion of the first semiconductor fin, the top region including the other of n-type and p-type dopant; a bottom terminal electrically connected to the bottom region; and a top terminal electrically connected to the top region at the top portion of the first semiconductor fin.

IC device including back-end-of-line (BEOL) transistors with crystalline channel material. A BEOL crystalline seed may be formed over a dielectric layer that has been planarized over a front-end-of-line (FEOL) transistor level that employs a monocrystalline substrate semiconductor. The BEOL crystalline seed may be epitaxial to the substrate semiconductor, or may have crystallinity independent of that of the substrate semiconductor. The BEOL crystalline seed may comprise a first material having a higher melt temperature than a melt material formed over the seed and over the dielectric layer. Through rapid melt growth, the melt material may be heated to a temperature sufficient to transition from an as-deposited state to a more crystalline state that is derived from, and therefore associated with, the BEOL crystalline seed. A BEOL transistor may then be fabricated from the crystallized material.

A power amplifier apparatus includes a semiconductor substrate, a plurality of first transistors on the semiconductor substrate, a plurality of second transistors, at least one collector terminal electrically connected to collectors of the plurality of first transistors, a first inductor having a first end electrically connected to the collector terminal and a second end electrically connected to a power supply potential, at least one emitter terminal electrically connected to emitters of the plurality of second transistors and adjacent to the collector terminal in a second direction, a second inductor having a first end electrically connected to the emitter terminal and a second end electrically connected to a reference potential, and at least one capacitor having a first end electrically connected to the collectors of the plurality of first transistors and a second end electrically connected to the emitters of the plurality of second transistors.

An IC chip includes a logic circuit cells array and a static random access memory (SRAM) cells array. The logic circuit cells array includes a plurality of logic circuit cells abutted to one another in a first direction. The logic circuit cells array includes one or more continuous first fin lines that each extends across at least three of the abutted logic circuit cells in the first direction. The static random access memory (SRAM) cells array includes a plurality of SRAM cells abutted to one another in the first direction. The SRAM cells array includes discontinuous second fin lines.

Integrated circuits including vertical diodes. In an example, a first transistor is above a second transistor. The first transistor includes a first semiconductor body extending laterally from a first source or drain region. The first source or drain region includes one of a p-type dopant or an n-type dopant. The second transistor includes a second semiconductor body extending laterally from a second source or drain region. The second source or drain region includes the other of the p-type dopant or the n-type dopant. The first source or drain region and second source or drain region are at least part of a diode structure, which may have a PN junction (e.g., first and second source/drain regions are merged) or a PIN junction (e.g., first and second source/drain regions are separated by an intrinsic semiconductor layer, or a dielectric layer and the first and second semiconductor bodies are part of the junction).