A method of forming an epitaxial stack on a plurality of substrates is provided. In a preferred embodiment, the method comprises providing a semiconductor processing apparatus. This semiconductor processing apparatus comprises a process chamber and a carousel for stationing a wafer boat before or after processing in the process chamber. The method further comprises loading the wafer boat into the process chamber, the wafer boat comprising the plurality of substrates. The method further comprises processing the plurality of substrates in the process chamber, thereby forming, on the plurality of substrates, the epitaxial stack. This epitaxial stack has a pre-determined thickness. The processing comprises unloading the wafer boat, one or more times, from the process chamber to the carousel until the epitaxial stack reaches the pre-determined thickness.

A heterostructure, includes: a substrate; and a buffer layer that includes a plurality of layers having a composition Al.sub.xIn.sub.yGa.sub.1-x-yN, where x≤1 and y≥0; wherein the buffer layer has a first region that includes at least two layers, a second region that includes at least two layers, and a third region that includes at least two layers.

A method of making a crystallographically-oriented metallic film with a two-dimensional crystal layer, comprising the steps of providing a metal film on a substrate, transferring a two-dimensional crystal layer onto the metal film and forming a two-dimensional crystal layer on metal film complex, heating the two-dimensional crystal layer on metal film complex, and forming a crystallographically-oriented metallic film with a two-dimensional crystal layer. A crystallographically-oriented metallic film with a two-dimensional crystal layer, comprising a substrate, a metal film on the substrate, a two-dimensional crystal layer on the metal film on the substrate, and a tunable microstructure within the porous metal/two-dimensional crystal layer on the substrate, wherein the metal film has crystallographic registry to the two-dimensional crystal layer.

An exemplary embodiment of the present disclosure provides a method of fabricating a semiconductor device, comprising: providing a substrate, the substate comprising a base layer and two or more planar heteroepitaxial layers deposited on the base layer, the two or more heteroepitaxial layers comprising a first epitaxial layer having a first lattice constant and a second epitaxial layer having a second lattice constant different than the first lattice constant; etching the substrate to form one or more mesas; and depositing one or more non-planar overgrowth layers on the etched substrate.

A substrate comprising a III-N base layer comprising a first portion and a second portion, the first portion of the III-N base layer having a first natural lattice constant and a first dislocation density; and a first III-N layer having a second natural lattice constant and a second dislocation density on the III-N base layer, the first III-N layer having a thickness greater than 10 nm. An indium fractional composition of the first III-N layer is greater than 0.1; the second natural lattice constant is at least 1% greater than the first natural lattice constant; a strain-induced lattice constant of the first III-N layer is greater than 1.0055 times the first natural lattice constant; and the second dislocation density is less than 1.5 times the first dislocation density.

An apparatus comprising a substrate and a thin gate oxide nanosheet device located on the substrate, having a first plurality of nanosheet layers, wherein each of the first plurality of nanosheet layers has a first thickness located at the center of the nanosheet. A thick gate oxide nanosheet device located on the substrate, having a second plurality of nanosheet layers, wherein each of the second plurality of nanosheet layers has a second thickness and wherein the first thickness is less than the second thickness.

A method includes etching a semiconductor substrate to form a trench, with the semiconductor substrate having a sidewall facing the trench, and depositing a first semiconductor layer extending into the trench. The first semiconductor layer includes a first bottom portion at a bottom of the trench, and a first sidewall portion on the sidewall of the semiconductor substrate. The first sidewall portion is removed to reveal the sidewall of the semiconductor substrate. The method further includes depositing a second semiconductor layer extending into the trench, with the second semiconductor layer having a second bottom portion over the first bottom portion, and a second sidewall portion contacting the sidewall of the semiconductor substrate. The second sidewall portion is removed to reveal the sidewall of the semiconductor substrate.

Disclosed herein are a III-N semiconductor structure manufactured by growing a III-N material on a superlattice structure layer, formed of AlGaN and InAlN materials, which serves as a buffer layer, and a method for manufacturing the same. The disclosed III-N semiconductor structure includes: a substrate including a silicon material; a seed layer formed on the substrate and including an aluminum nitride (AlN) material; a superlattice structure layer formed by sequentially depositing a plurality of superlattice units on the seed layer; and a cap layer formed on the superlattice structure layer and including a gallium nitride (GaN) material, wherein the superlattice units are each composed of a first layer including an AlxGa1-xN wherein 0≤x≤1 and a second layer including an InyAl1-yN wherein 0y≤0.4.

A method for forming a semiconductor device structure is provided. The method includes forming an n-type doped region in a semiconductor substrate and forming a semiconductor stack over the semiconductor substrate. The semiconductor stack has multiple sacrificial layers and multiple semiconductor layers laid out alternately. The method also includes introducing n-type dopants from the n-type doped region into the semiconductor stack during the forming of the semiconductor stack. The method further includes patterning the semiconductor stack to form a fin structure and forming a dummy gate stack to wrap around a portion of the fin structure. In addition, the method includes removing the dummy gate stack and the sacrificial layers to release multiple semiconductor nanostructures made up of remaining portions of the semiconductor layers. The method includes forming a metal gate stack to wrap around the semiconductor nanostructures.

A method for making a semiconductor device may include forming a semiconductor layer, and forming a superlattice adjacent the semiconductor layer and including stacked groups of layers. Each group of layers may include stacked base semiconductor monolayers defining a base semiconductor portion, and at least one oxygen monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The at least one oxygen monolayer of a given group of layers may comprise an atomic percentage of .sup.18O greater than 10 percent.