A method of forming a germanium antimony tellurium (GeSbTe) layer includes forming a germanium antimony (GeSb) layer by repeatedly performing a GeSb supercycle; and forming the GeSbTe layer by performing a tellurization operation on the GeSb layer, wherein the GeSb supercycle includes performing at least one GeSb cycle; and performing at least one Sb cycle, the GeSbTe has a composition of Ge.sub.2Sb.sub.2+aTe.sub.5+b, in which a and b satisfy the following relations: −0.2<a<0.2 and −0.5<b<0.5.

A method for forming an integrated circuit device is provided. The method includes forming a transistor over a frontside of a substrate; forming an interconnect structure over the transistor; depositing a first transition metal layer over the interconnect structure; performing a plasma treatment to turn the first transition metal layer into a first transition metal dichalcogenide layer; forming a dielectric layer over the first transition metal dichalcogenide layer; forming a first gate electrode over the dielectric layer and a first portion of the first transition metal dichalcogenide layer; and forming a first source contact and a first drain contact respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer, the first portion of the first transition metal dichalcogenide layer being between the second and third portions of the first transition metal dichalcogenide layers.

This disclosure relates to methods of growing crystalline layers on amorphous substrates by way of an ultra-thin seed layer, methods for preparing the seed layer, and compositions comprising both. In an aspect of the invention, the crystalline layers can be thin films. In a preferred embodiment, these thin films can be free-standing.

The present invention relates to various high quality n-type and p-type doped gallium-based semiconductor materials, electronic components incorporating these materials, and processes of producing these materials. In particular, The present invention relates processes to achieve high quality, uniform doping of a whole wafer or a thin layer of gallium-based semiconductor materials for various applications such as a vertical power transistor or diode.

A first mask material layer on a Si pillar 7a and a first material layer around a side surface of a top portion of the Si pillar 7a are formed. A second material layer is then formed on an outer periphery of the first material layer. The first mask material layer and the first material layer are then etched by using the second material layer as a mask. A thin SiGe layer, a p.sup.+ layer 23a, and a SiO.sub.2 layer 24a are then formed in a recessed portion formed around the Si pillar 7a. The exposed side surface of the thin SiGe layer is oxidized to form a SiO.sub.2 layer 26a. A TiN layer and a W layer, which are gate conductor layers, are etched by using the SiO.sub.2 layers 24a and 26a as masks to form a TiN layer 29a and a W layer 30a. In plan view, the Si pillar 7a, the p.sup.+ layer 23a with a small diode junction resistance, and the TiN layer 29a and the W layer 30a, which are gate line conductor layers, thus have a self-alignment relationship, and the p.sup.+ layer 23a and the TiN layer 29a are self-aligned with each other with the HfO.sub.2 layer 28 and the SiO.sub.2 layer 26a therebetween in the vertical direction.

Transition metal dichalcogenide films and methods for depositing transition metal dichalcogenide films on a substrate are described. Methods for converting transition metal oxide films to transition metal dichalcogenide films are also described. The substrate is exposed to a precursor and a chalcogenide reactant to form the transition metal dichalcogenide film. The exposures can be sequential or simultaneous.

Disclosed are an electronic device including a two-dimensional material, and a method of fabricating the electronic device. The electronic device may include a first metal layer including a transition metal, a second metal layer on the first metal layer and including gold (Au), and a two-dimensional material layer between the first metal layer and the second metal layer. The two-dimensional material layer may include a transition metal dichalcogenide (TMD). The two-dimensional material layer may be formed as a chalcogen element diffuses into the second metal layer and reacts with the transition metal of the first metal layer adjacent to the second metal layer.

Transistor structures including a non-planar body that has an active portion comprising a semiconductor material of a first height that is variable, and an inactive portion comprising an oxide of the semiconductor material of a second variable height, complementary to the first height. Gate electrodes and source/drain terminals may be coupled through a transistor channel having any width that varies according to the first height. Oxidation of a semiconductor material may be selectively catalyzed to convert a desired portion of a non-planar body into the oxide of the semiconductor material. Oxidation may be enhanced through the application of a catalyst, such as one comprising metal and oxygen, for example.

A method for selectively etching layers of a first material with respect to layers of a second material in a stack is provided. The layers of the first material are partially etched with respect to the layers of the second material. A deposition layer is selectively deposited on the stack, wherein portions of the deposition layer covering the layers of the second material are thicker than portions covering the layers of the first material, the selective depositing comprising providing a first reactant, purging some of the first reactant, wherein some undeposited first reactant is not purged, and providing a second reactant, wherein the undeposited first reactant combines with the second reactant and selectively deposits on the layers of the second material with respect to the layers of the first material. The layers of the first material are selectively etched with respect to the layers of the second material.

A method for producing a transition metal dichalcogenide-graphene heterojunction composite, the method includes: transferring a graphene onto a flexile substrate; depositing a transition metal layer on the flexible substrate onto which the graphene has been transferred; and injecting a gas containing plasma-treated sulfur (S) onto the flexile substrate onto which the transition metal layer has been deposited, is disclosed.