Abstract: A semiconductor device includes an extremely thin semiconductor-on-insulator substrate (ETSOI) having a base substrate, a thin semiconductor layer and a buried dielectric therebetween. A device channel is formed in the thin semiconductor layer. Source and drain regions are formed at opposing positions relative to the device channel. The source and drain regions include an n-type material deposited on the buried dielectric within a thickness of the thin semiconductor layer. A gate structure is formed over the device channel.

Abstract: A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a first substrate. The spreading layer has at least one monolayer. A stressor layer is formed on the spreading layer. The stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein at least the closest monolayer remains on the stressor layer. The at least one monolayer is stamped against a second substrate to adhere remnants of the two-dimensional material on the at least one monolayer to the second substrate to provide a single monolayer on the stressor layer. The single monolayer is transferred to a third substrate.

Abstract: Methods for removing a material layer from a base substrate utilizing spalling in which mode III stress, i.e., the stress that is perpendicular to the fracture front created in the base substrate, during spalling is reduced. The substantial reduction of the mode III stress during spalling results in a spalling process in which the spalled material has less surface roughness at one of its' edges as compared to prior art spalling processes in which the mode III stress is present and competes with spalling.

Abstract: A photovoltaic device and method include depositing a metal film on a substrate layer. The metal film is annealed to form islands of the metal film on the substrate layer. The substrate layer is etched using the islands as an etch mask to form pillars in the substrate layer.

Abstract: A semiconductor device includes a substrate and a p-doped layer including a doped III-V material on the substrate. A dielectric interlayer is formed on the p-doped layer. An n-type layer is formed on the dielectric interlayer, the n-type layer including a high band gap II-VI material to form an electronic device.

Abstract: A method for forming a heteroepitaxial layer includes forming an epitaxial grown layer on a monocrystalline substrate and patterning the epitaxial grown layer to form fins. The fins are converted to porous fins. A surface of the porous fins is treated to make the surface suitable for epitaxial growth. Lattice mismatch is compensated for between an epitaxially grown monocrystalline layer grown on the surface and the monocrystalline substrate by relaxing the epitaxially grown monocrystalline layer using the porous fins to form a relaxed heteroepitaxial interface with the monocrystalline substrate.

Abstract: Methods for forming a photovoltaic device include forming a buffer layer between a transparent electrode and a p-type layer. The buffer layer includes a work function that falls substantially in a middle of a barrier formed between the transparent electrode and the p-type layer to provide a greater resistance to light induced degradation. An intrinsic layer and an n-type layer are formed over the p-type layer.

Abstract: A semiconductor device includes a substrate and a p-doped layer including a doped III-V material on the substrate. An n-doped layer is formed on the p-doped layer, the n-doped layer including a doped III-V material. A contact interface layer is formed on the n-doped layer. The contact interface layer includes a II-VI material. A contact metal is formed on the contact interface layer to form an electronic device.

Abstract: A method of making a semiconductor device includes forming a first fin in a first semiconducting material layer disposed over a substrate, the first semiconducting material layer comprising an element in a first concentration; and forming a second fin in a second semiconducting material layer disposed over the substrate and adjacent to the first semiconducting material layer, the second semiconducting material layer comprising the element in a second concentration; wherein the first concentration is different than the second concentration.

Abstract: A method of making a semiconductor device includes forming a first fin in a first semiconducting material layer disposed over a substrate, the first semiconducting material layer comprising an element in a first concentration; and forming a second fin in a second semiconducting material layer disposed over the substrate and adjacent to the first semiconducting material layer, the second semiconducting material layer comprising the element in a second concentration; wherein the first concentration is different than the second concentration.

Abstract: Compound semiconductor devices and methods for fabricating compound semiconductor devices (e.g., III-V devices) based on aspect ratio trapping are provided in which economical and environmentally friendly chemical mechanical polishing techniques are implemented to minimize waste of, e.g., III-V precursor material, minimize production costs, and minimize environmental impact from toxic waste generated from chemical mechanical polishing of III-V films.

Abstract: A method of fabricating a semiconductor device where: (i) the fins are formed over a porous semiconductor material layer (for example, a silicon layer); and (ii) the porous semiconductor layer is then oxidized to form an insulator layer (for example, a SiO2 buried oxide layer). The pores in the porous semiconductor layer facilitate reliable oxidation of the insulator layer by allowing penetration of gaseous oxygen (O2) throughout the layer as it is oxidized to form the insulator layer. In some of these embodiments, a thin non-porous semiconductor layer is located over the porous semiconductor layer (prior to its oxidation) to allow strained epitaxial growth of material to be used in making source regions and drain regions of the finished semiconductor device (for example, a FINFET).

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a semiconductor substrate, and forming a gate structure on a channel region portion of the fin structure. A source region and a drain region are formed on a source region portion and a drain region portion of the fin structure on opposing sides of the channel portion of the fin structure. At least one sidewall of the source region portion and the drain region portion of the fin structure is exposed. A metal semiconductor alloy is formed on the at least one sidewall of the source region portion and the drain region portion of the fin structure that is exposed.

Abstract: Methods are provided to fabricate semiconductor devices, e.g., FinFET devices, having fin channel structures formed of silicon-germanium alloy layers with uniform thickness. For example, a method includes forming a semiconductor fin structure having sidewalls that define a first width of the semiconductor fins structure, and a hard mask layer disposed on a top surface of the semiconductor fin structure. Portions of the sidewalls are etched to form recessed sidewalls that define a thinned portion, wherein a distance between the recessed sidewalls defines a second width of the thinned portion of the semiconductor fin structure, which is less than the first width. Facetted semiconductor alloy layers are formed on the recessed sidewalls, and then anisotropically etched using the hard mask layer as an etch mask to form planarized semiconductor alloy layers of uniform thickness on the recessed sidewalls of the thinned portion of the semiconductor fin structure.

Abstract: A method of forming an epitaxial semiconductor material that includes forming a graphene layer on a semiconductor and carbon containing substrate and depositing a metal containing monolayer on the graphene layer. An epitaxial layer of a gallium containing material is formed on the metal containing monolayer. A layered stack of the metal containing monolayer and the epitaxial layer of gallium containing material is cleaved from the graphene layer that is present on the semiconductor and carbon containing substrate.

Abstract: A handle substrate having at least one metallization region is provided on a stressor layer that is located above a base substrate such that the at least one metallization region is in contact with a surface of the stressor layer. An upper portion of the base substrate is spalled, i.e., removed, to provide a structure comprising, from bottom to top, a spalled material portion of the base substrate, the stressor layer and the handle substrate containing the at least one metallization region in contact with the surface of the stressor layer.

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a semiconductor substrate, and forming a gate structure on a channel region portion of the fin structure. A source region and a drain region are formed on a source region portion and a drain region portion of the fin structure on opposing sides of the channel portion of the fin structure. At least one sidewall of the source region portion and the drain region portion of the fin structure is exposed. A metal semiconductor alloy is formed on the at least one sidewall of the source region portion and the drain region portion of the fin structure that is exposed.

Abstract: A photovoltaic device and method include a doped germanium-containing substrate, an emitter contact coupled to the substrate on a first side and a back contact coupled to the substrate on a side opposite the first side. The emitter includes at least one doped layer of an opposite conductivity type as that of the substrate and the back contact includes at least one doped layer of the same conductivity type as that of the substrate. The at least one doped layer of the emitter contact or the at least one doped layer of the back contact is in direct contact with the substrate, and the at least one doped layer of the emitter contact or the back contact includes an n-type material having an electron affinity smaller than that of the substrate, or a p-type material having a hole affinity larger than that of the substrate.

Abstract: Described herein is a method for manufacturing a stack of semiconductor materials in which a growth substrate is separated from the stack after a semiconductor material, e.g., a Group III nitride semiconductor material, is grown on the substrate. The separation is effected in a spalling procedure in which spalling-facilitating layers are deposited over a protective cap layer that is formed over the Group III-nitride semiconductor material. Such spalling-facilitating layers may include a handle layer, a stressor layer, and an optional adhesion layer. The protective cap layer protects the Group III-nitride from being damaged by the depositing of one or more of the spalling-facilitating layers. After spalling to remove the growth substrate, additional processing steps are taken to provide a semiconductor device that includes undamaged semiconductor material. In one arrangement, the semiconductor material is GaN and includes p-doped GaN region that was undamaged during manufacturing.

Abstract: Methods for removing a material layer from a base substrate utilizing spalling in which mode III stress, i.e., the stress that is perpendicular to the fracture front created in the base substrate, during spalling is reduced. The substantial reduction of the mode III stress during spalling results in a spalling process in which the spalled material has less surface roughness at one of its' edges as compared to prior art spalling processes in which the mode III stress is present and competes with spalling.