A lateral bipolar junction transistor (LBJT) device that includes an intrinsic III-V semiconductor material having a first band gap; and a base region present on the intrinsic III-V semiconductor material. The base region is composed of an III-V semiconductor material having a second band gap that is less than the first band gap. Emitter and collector regions present on opposing sides of the base region. The emitter and collector regions are composed of epitaxial III-V semiconductor material that is present on the intrinsic III-V semiconductor material.

A lattice matched epitaxial oxide interlayer is disposed between each semiconductor layer of a graded buffer layer material stack. Each lattice matched epitaxial oxide interlayer inhibits propagation of threading dislocations from one semiconductor layer of the graded buffer layer material stack into an overlying semiconductor layer of the graded buffer layer material stack. This allows for decreasing the thickness of each semiconductor layer within the graded buffer layer material stack. The topmost semiconductor layer of the graded buffer layer material stack, which is a relaxed layer, contains a lower defect density than the other semiconductor layers of the graded buffer layer material stack.

A method provides a first substrate supporting an insulator layer having trenches formed therein; filling the trenches using an epitaxial growth process with at least semiconductor material; planarizing tops of the filled trenches; forming a first layer of dielectric material on a resulting planarized surface; inverting the first substrate wafer to place the first layer of dielectric material in contact with a second layer of dielectric material on a second substrate; bonding the first substrate to the second substrate through the first and second layers of dielectric material to form a common layer of dielectric material; and removing the first substrate and a first portion of the filled trenches to leave a second portion of the filled trenches disposed upon the common dielectric layer. The removed first portion of the filled trenches contains dislocation defects. The method then removes the insulator layer to leave a plurality of Fin structures.

A method of forming Si or Ge-based and III-V based vertically integrated nanowires on a single substrate and the resulting device are provided. Embodiments include forming first trenches in a Si, Ge, III-V, or Si.sub.xGe.sub.1-x substrate; forming a conformal SiN, SiO.sub.xC.sub.yN.sub.z layer over side and bottom surfaces of the first trenches; filling the first trenches with SiO.sub.x; forming a first mask over portions of the Si, Ge, III-V, or Si.sub.xGe.sub.1-x substrate; removing exposed portions of the Si, Ge, III-V, or Si.sub.xGe.sub.1-x substrate, forming second trenches; forming III-V, III-V.sub.xM.sub.y, or Si nanowires in the second trenches; removing the first mask and forming a second mask over the III-V.sub.xM.sub.y, or Si nanowires and intervening first trenches; removing the SiO.sub.x layer, forming third trenches; and removing the second mask.

Embodiments described herein generally relate to a substrate processing system, such as an etch processing system. In one embodiment, a method of processing a substrate is disclosed herein. The method includes removing a native oxide from a surface of the substrate, baking the substrate in a pre-treatment thermal chamber such that double atomic steps are formed on the surface of the substrate, and forming an epitaxial layer on the substrate after the substrate is baked.

Disclosed are methods of growing III-V epitaxial layers on a substrate, semiconductor structures thus obtained, and devices comprising such semiconductor structures. An example semiconductor substrate includes a substrate and a buffer layer on top of the substrate, where a conductive path is present between the substrate and buffer layer. A conductive path may be present in the conductive interface, and the conductive path may be interrupted by one or more local electrical isolations. The local electrical isolation(s) may be positioned with the device such that at least one of the local electrical isolation(s) is located between a high voltage terminal and a low voltage terminal of the device.

A semiconductor compound structure and a method of fabricating the semiconductor compound structure using graphene or carbon nanotubes, and a semiconductor device including the semiconductor compound structure. The semiconductor compound structure includes a substrate; a buffer layer disposed on the substrate, and formed of a material including carbons having hexagonal crystal structures; and a semiconductor compound layer grown and formed on the buffer layer.

The invention provides the use of at least one binary group 15 element compound of the general formula R.sup.1R.sup.2E-E′R.sup.3R.sup.4 (I) or R.sup.5E(E′R.sup.6R.sup.7)2 (II) as the educt in a vapor deposition process. In this case, R.sup.1, R.sup.2, R.sup.3 and R.sup.4 are independently selected from the group consisting of H, an alkyl radical (C1-C10) and an aryl group, and E and E′ are independently selected from the group consisting of N, P, As, Sb and Bi. This use excludes hydrazine and its derivatives. The binary group 15 element compounds according to the invention allow the realization of a reproducible production and/or deposition of multinary, homogeneous and ultrapure 13/15 semiconductors of a defined combination at relatively low process temperatures. This makes it possible to completely waive the use of an organically substituted nitrogen compound such as 1.1 dimethyl hydrazine as the nitrogen source, which drastically reduces nitrogen contaminations—compared to the 13/15 semiconductors and/or 13/15 semiconductor layers produced with the known production methods.

One illustrative method disclosed herein includes forming a gate structure above a portion of a fin and performing a first epitaxial growth process to form a silicon-carbide (SiC) semiconductor material above the fin in the source and drain regions of a FinFET device. In this example, the method also includes performing a heating process so as to form a source/drain graphene contact from the silicon-carbide (SiC) semiconductor material in both the source and drain regions of the FinFET device and forming first and second source/drain contact structures that are conductively coupled to the source/drain graphene contact in the source region and the drain region, respectively, of the FinFET device.

A method for forming a semiconductor device comprises forming an insulator layer on a semiconductor substrate, removing portions of the insulator layer to form a first cavity and a second cavity, the first cavity exposing a first portion of the semiconductor substrate an the second cavity exposing a second portion of the semiconductor substrate, growing a first semiconductor material in the first cavity and the second cavity. Growing a second semiconductor material on the first semiconductor material in the first cavity and the second cavity, growing a third semiconductor material on the second semiconductor material in the first cavity and the second cavity. Forming a mask over the third semiconductor material in the first cavity, removing the third semiconductor material from the second cavity to expose the second semiconductor material in the second cavity, and growing a fourth semiconductor material on the second semiconductor material in the second cavity.