Devices comprising germanium nanosheets are described herein. Methods of forming such germanium nanosheets and devices including such germanium nanosheets are also described.

A device includes a layer including a first III-Nitride (III-N) material, a channel layer including a second III-N material, a release layer including nitrogen and a transition metal, where the release layer is between the first III-N material and the second III-N material. The device further includes a polarization layer including a third III-N material above the release layer, a gate structure above the polarization layer, a source structure and a drain structure on opposite sides of the gate structure where the source structure and the drain structure each include a fourth III-N material. The device further includes a source contact on the source structure and a drain contact on the drain structure.

Devices comprising germanium nanosheets are described herein. Methods of forming such germanium nanosheets and devices including such germanium nanosheets are also described.

A method for monolithically depositing a monocrystalline IV-IV layer that glows when excited and that is composed of a plurality of elements of the IV main group, in particular a GeSn or Si—GeSn layer, the IV-IV layer having a dislocation density less than 6 cm.sup.−2, on an IV substrate, in particular a silicon or germanium substrate, including the following steps: providing a hydride of a first IV element (A), such as Ge.sub.2H.sub.6 or Si.sub.2H.sub.6; providing a halide of a second IV element (B), such as SnCl.sub.4; heating the substrate to a substrate temperature that is less than the decomposition temperature of the pure hydride or of a radical formed therefrom and is sufficiently high that atoms of the first element (A) and of the second element (B) are integrated into the surface in crystalline order, wherein the substrate temperature lies, in particular, in a range between 300° C. and 475° C.; producing a carrier gas flow of an inert carrier gas, in particular N.sub.2, Ar, He, which in particular is not H.sub.3; transporting the hydride and the halide and decomposition products arising therefrom to the surface at a total pressure of at most 300 mbar; depositing the IV-IV layer, or a layer sequence consisting of IV-IV layers of the same type, having a thickness of at least 200 nm, wherein the deposited layer is, in particular, a Si.sub.yGe.sub.1−x−ySn layer, with x>0.08 and y≤1.

Methods and systems for selectively depositing material, such as doped semiconductor material, are disclosed. An exemplary method includes providing a substrate, comprising a first area comprising a first material and a second area comprising a second material, selectively depositing a first doped semiconductor layer overlying the first material relative to the second material and selectively depositing a second doped semiconductor layer overlying the first doped semiconductor layer relative to the second material.

A method for depositing a monocrystalline semiconductor layer consisting of a first element and a second element, wherein the first elements is fed as part of a hydride, and the second element is fed as part of a halide, together with a carrier gas, into a process chamber of a reactor, wherein radicals are produced from the hydride at a distance away from a surface of a semiconductor substrate, wherein at a temperature below a decomposition temperature of the radicals, at a total pressure of the gas in the process chamber sufficiently low to avoid a reverse reaction of the radicals in the gas phase the radicals and the halide are brought to the surface of the semiconductor substrate which is heated to a substrate temperature lower than the decomposition temperature, wherein heat released during a first exothermic chemical reaction drives a second endothermic chemical reaction.

A method includes forming a first semiconductor layer over a substrate; forming a second semiconductor layer over the first semiconductor layer; forming a dummy gate structure over the second semiconductor layer; performing an etching process to form a recess in the first and second semiconductor layers; forming a epitaxy structure over in the recess, wherein the epitaxy structure is in contact with the first and second semiconductor layers; performing a solid phase diffusion process to form a doped region in the epitaxy structure, in which the doped region is in contact with the second semiconductor layer and is separated from the first semiconductor layer; and replacing the dummy gate structure with a metal gate structure.

A display device includes: a substrate including a display area and a non-display area; a gate driver disposed on the substrate in the non-display area and including a plurality of stages that generate a gate signal and output the gate signal to the display area; a switching transistor and a driving transistor disposed on the substrate in the display area; and a light emitting diode connected to the driving transistor, wherein each of the plurality of stages may include a plurality of transistors, wherein a channel layer of the driving transistor includes a first oxide semiconductor material, and a channel layer of the plurality of transistors included in each of the plurality of stages includes a second oxide semiconductor material, wherein the first oxide semiconductor material is different from the second oxide semiconductor material, and wherein the second oxide semiconductor material may include tin.

A method includes forming a fin structure over a substrate; forming a source/drain structure adjoining the fin structure, in which the source/drain structure includes tin; and exposing the source/drain structure to a boron-containing gas to diffuse boron into the source/drain structure to form a doped region in the source/drain structure.

The present invention discloses a semiconductor structure and a method for manufacturing the semiconductor structure. The semiconductor structure includes: a substrate; and at least one composition adjusting layer disposed above the substrate; wherein each of the at least one composition adjusting layer is made of a semiconductor compound, the semiconductor compound at least comprises a first element and a second element, and an atomic number of the first element is less than an atomic number of the second element, wherein in each of the at least one composition adjusting layer, along an epitaxial direction of the substrate, an atomic percentage of the first element in a compound composition is gradually decreased at first and then gradually increased, a thickness of a gradual decrease section is greater than a thickness of a gradual increase section.