Semiconductor devices comprising two-dimensional (2D) materials and methods of manufacture thereof are described. In an embodiment, a method for manufacturing a semiconductor device comprising 2D materials may include: epitaxially forming a first 2D material layer on a substrate; and epitaxially forming a second 2D material layer over the first 2D material layer, the first 2D material layer and the second 2D material layer differing in composition.

The present invention relates to atomically-thin channel materials with crystallographically uniform interfaces to atomically-thin commensurate graphene electrodes and/or nanoribbons separated by nanogaps that allow for nanoelectronics based on quantum transport effects and having significantly improved contact resistances.

A device includes a substrate, insulation regions extending into the substrate, a first semiconductor region between the insulation regions and having a first valence band, and a second semiconductor region over and adjoining the first semiconductor region. The second semiconductor region has a compressive strain and a second valence band higher than the first valence band. The second semiconductor region includes an upper portion higher than top surfaces of the insulation regions to form a semiconductor fin, and a lower portion lower than the top surfaces of the insulation regions. The upper portion and the lower portion are intrinsic. A semiconductor cap adjoins a top surface and sidewalls of the semiconductor fin. The semiconductor cap has a third valence band lower than the second valence band.

An epitaxial group-ill-nitride buffer-layer structure is provided on a heterosubstrate, wherein the buffer-layer structure has at least one stress-management layer sequence including an interlayer structure arranged between and adjacent to a first and a second group-ill-nitride layer, wherein the interlayer structure comprises a group-ill-nitride interlayer material having a larger band gap than the materials of the first and second group-ill-nitride layers, and wherein a p-type-dopant-concentration profile drops, starting from at least 11018 cm-3, by at least a factor of two in transition from the interlayer structure to the first and second group-ill-nitride layers.

Metal layout for radio-frequency (RF) switches. In some embodiments, an RF switching device can include a plurality of field-effect transistors (FETs) arranged in series to form a stack. Each of at least some of the FETs can include a source contact and a drain contact, a first group of fingers electrically connected to the source contact, and a second group of fingers electrically connected to the drain contact and arranged in an interleaved configuration with the first group of fingers. At least some of the first group of fingers and the second group of fingers can include a first metal M1 and a second metal M2 arranged in a stack. At least one of the first metal M1 and the second metal M2 can include a tapered portion to yield a current carrying capacity that varies as a function of location along a direction in which the corresponding finger extends.

A semiconductor device includes a gate positioned on a substrate; a nanosheet that extends through the gate, protrudes from a sidewall of the gate, and forms a recess between the substrate and the nanosheet; a dielectric spacer disposed in the recess; a source/drain contact positioned on a source/drain disposed on the substrate adjacent to the gate; an air gap spacer positioned along the sidewall of the gate and in contact with a dielectric material disposed on the nanosheet, the air gap spacer being in contact with the source/drain contact; and an interlayer dielectric (ILD) disposed on the air gap spacer.

There are disclosed herein various implementations of a compact high-voltage semiconductor package. In one exemplary implementation, such a semiconductor package includes a power transistor, as well as a drain contact, a source contact, and a gate contact to provide external connections to the power transistor. The semiconductor package also includes a contour element formed between the drain contact and the source contact in the semiconductor package. The contour element increases a creepage distance between the drain contact and the source contact in the semiconductor package so as to increase a breakdown voltage of the semiconductor package.

In an embodiment, a semiconductor device includes a Group III-nitride-based High Electron Mobility Transistor (HEMT) configured as a bidirectional switch. The Group III nitride-based HEMT includes a first input/output electrode, a second input/output electrode, a gate structure arranged between the first input/output electrode and the second input/output electrode, and a field plate structure.

A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate having a first region and a second region; forming a gate layer on the substrate; forming a first gate dielectric layer on the gate layer; forming a first channel layer on the first region and a second channel layer on the second region; and forming a first source/drain on the first channel layer and a second source/drain on the second channel layer.

An electronic device can include a HEMT including at least two channel layers. In an embodiment, a lower semiconductor layer overlies a lower channel layer, wherein the lower semiconductor layer has an aluminum content that is at least 10% of a total metal content of the lower semiconductor layer. An upper semiconductor layer overlies the upper channel layer, wherein the upper semiconductor layer has an aluminum content that is greater as compared to the lower semiconductor layer. In another embodiment, an electronic device can include stepped source and drain electrodes, so that lower contact resistance can be achieved. In a further embodiment, an absolute value of a difference between pinch-off or threshold voltages between different channel layers is greater than 1 V and allows current to be turned on or turned off for a channel layer without affecting another channel layer.