Abstract: A method for forming epitaxial SiGe of a PMOS transistor. In an example embodiment, the method may include providing a semiconductor wafer having a PMOS transistor gate stack, extension sidewalls, source/drain extension regions, and active regions. The method may also include performing a recess etch of the active regions and forming epitaxial SiGe within the recessed active regions by forming a selective epi SiGe region coupled to the surface of the recessed active regions and a selective carbon-doped epitaxial cap layer coupled to the selective epi SiGe region.

Abstract: The embodiments of the present invention generally relates to methods for enhancing the light extraction by surface roughening of the bottom n-GaN layer and/or top p-GaN layer so that the internal light from the active region is scattered outwardly to result in a higher external quantum efficiency. In one embodiment, a surface roughening process is performed on the n-GaN layer to form etching pits in a top surface of the n-GaN layer. Once the etching pits are formed, growth of the n-GaN material may be resumed on the roughened n-GaN layer to partially fill the etching pits, thereby forming air voids at the interface of the n-GaN layer and the subsequent, re-growth n-GaN layer. These air voids provide one or more localized regions with indices of reflection different from that of the n-GaN layer, such that the internal light generated by the active layers (e.g., the InGaN MQW layer), when passing through the n-GaN layer, is scattered by voids or bubbles.

Abstract: Methods and apparatus for depositing thin films incorporating the use of a surfactant are described. Methods and apparatuses include a deposition process and system comprising multiple isolated processing regions which enables rapid repetition of sub-monolayer deposition of thin films. The use of surfactants allows the deposition of high quality epitaxial films at lower temperatures having low values of surface roughness. The deposition of Group III-V thin films such as GaN is used as an example.

Abstract: A group III chalcogenide layer for interfacing a high-k dielectric to a III-V semiconductor surface and methods of forming the same. A III-V QWFET includes a gate stack which comprises a high-K gate dielectric layer disposed on an interfacial layer comprising a group III chalcogenide. In an embodiment, a III-V semiconductor surface comprising a native oxide is sequentially exposed to TMA and H2S provided in an ALD process to remove substantially all the native oxide and form an Al2S3 layer on the semiconductor surface.

Abstract: A method for fabricating a semiconductor device includes forming an AlN layer on a substrate made of silicon by supplying an Al source without supplying a N source and then supplying both the Al source and the N source, and forming a GaN-based semiconductor layer on the AlN layer after the forming of the AlN layer. The forming of the AlN layer grows the AlN layer so as to satisfy the following: 76500/x0.81<y<53800/x0.83 where x is a thickness of the AlN layer and y is an FWHM of a rocking curve of a (002) plane of the AlN layer.

Abstract: A method for manufacturing a plurality light emitting diodes includes providing a gallium nitride containing bulk crystalline substrate material configured in a non-polar or semi-polar crystallographic orientation, forming an etch stop layer, forming an n-type layer overlying the etch stop layer, forming an active region, a p-type layer, and forming a metallization. The method includes removing a thickness of material from the backside of the bulk gallium nitride containing substrate material. A plurality of individual LED devices are formed from at least a sandwich structure comprising portions of the metallization layer, the p-type layer, active layer, and the n-type layer. The LED devices are joined to a carrier structure.

Abstract: One embodiment of depositing a gallium nitride (GaN) film on a substrate comprises providing a source of indium (In) and gallium (Ga) and depositing a monolayer of indium (In) on the surface of the gallium nitride (GaN) film. The monolayer of indium (In) acts as a surfactant to modify the surface energy and facilitate the epitaxial growth of the film by suppressing three dimensional growth and enhancing or facilitating two dimensional growth. The deposition temperature is kept sufficiently high to enable the indium (In) to undergo absorption and desorption on the gallium nitride (GaN) film without being incorporated into the solid phase gallium nitride (GaN) film. The gallium (Ga) and indium (In) can be provided by a single source or separate sources.

Abstract: Provided is a Group III nitride-based compound semiconductor light-emitting device including aluminum regions. The Group III nitride-based compound semiconductor light-emitting device includes a sapphire substrate; aluminum regions which are formed on the substrate; an AlN buffer layer; an Si-doped GaN n-contact layer; an n-cladding layer formed of multiple layer units, each including an undoped In0.1Ga0.9N layer, an undoped GaN layer, and a silicon (Si)-doped GaN layer; an MQW light-emitting layer including alternately stacked eight well layers formed of In0.2Ga0.8N and eight barrier layers formed of GaN and Al0.06Ga0.94N; a p-cladding layer formed of multiple layers including a p-type Al0.3Ga0.7N layer and a p-type In0.08Ga0.92N layer; a p-contact layer having a layered structure including two p-type GaN layers having different magnesium concentrations; and an ITO light-transmitting electrode.

Abstract: A Group III-V Semiconductor device and method of fabrication is described. A high-k dielectric is interfaced to a confinement region by a chalcogenide region.

Abstract: One embodiment of depositing a gallium nitride (GaN) film on a substrate comprises providing a source of indium (In) and gallium (Ga) and depositing a monolayer of indium (In) on the surface of the gallium nitride (GaN) film. The monolayer of indium (In) acts as a surfactant to modify the surface energy and facilitate the epitaxial growth of the film by suppressing three dimensional growth and enhancing or facilitating two dimensional growth. The deposition temperature is kept sufficiently high to enable the indium (In) to undergo absorption and desorption on the gallium nitride (GaN) film without being incorporated into the solid phase gallium nitride (GaN) film. The gallium (Ga) and indium (In) can be provided by a single source or separate sources.

Abstract: A method for manufacturing an electronic-photonic device. Epitaxially depositing an n-doped III-V composite semiconductor alloy buffer layer on a crystalline surface of a substrate at a first temperature. Forming an active layer on the n-doped III-V epitaxial composite semiconductor alloy buffer layer at a second temperature, the active layer including a plurality of spheroid-shaped quantum dots. Depositing a p-doped III-V composite semiconductor alloy capping layer on the active layer at a third temperature. The second temperature is less than the first temperature and the third temperature. The active layer has a photoluminescence intensity emission peak in the telecommunication C-band.

Abstract: A semiconductor fabrication process includes forming a gate dielectric layer (120) overlying a substrate (101) that includes a III-V semiconductor compound. The gate dielectric layer is patterned to produce a gate dielectric structure (121) that has a substantially vertical sidewall (127), e.g., a slope of approximately 45° to 90°. A metal contact structure (130) is formed overlying the wafer substrate. The contact structure is laterally displaced from the gate dielectric structure sufficiently to define a gap (133) between the two. The wafer (100) is heat treated, which causes migration of at least one of the metal elements to form an alloy region (137) in the underlying wafer substrate. The alloy region underlies the contact structure and extends across all or a portion of the wafer substrate underlying the gap. An insulative or dielectric capping layer (140,150) is then formed overlying the wafer and covering the portion of the substrate exposed by the gap.

Abstract: A method of manufacturing a nitride semiconductor device includes the steps of; forming a stripping layer including In on a substrate; forming a nitride semiconductor layer on the stripping layer; causing a decomposition of the stripping layer by increasing a temperature of the stripping layer; irradiating the stripping layer with laser light; and separating the nitride semiconductor layer from the substrate.

Abstract: A fabricating method of Single Electron Transistor includes processing steps as follows: first, deposit the sealing material of gas molecule or atom state on the top-opening of the nano cylindrical pore, which having formed on the substrate, so that the diameter of said top-opening gradually reduce to become a reduced nano-aperture, whose opening diameter is smaller than that of said top-opening; then, keep the substrate in horizontal direction and tilt or rotate said substrate into tilt angle or rotation angle in coordination with tilt angle with the reduced nano-aperture as center respectively, and pass the deposit material of gas molecular or atom state through the reduced nano-aperture respectively. Thereby a Single Electron Transistor including island electrode, drain electrode, source electrode and gate electrode of nano-quantum dot with nano-scale is directly fabricated on the surface of said substrate.

Abstract: Embodiments described include straining transistor quantum well (QW) channel regions with metal source/drains, and conformal regrowth source/drains to impart a uni-axial strain in a MOS channel region. Removed portions of a channel layer may be filled with a junction material having a lattice spacing different than that of the channel material to causes a uni-axial strain in the channel, in addition to a bi-axial strain caused in the channel layer by a top barrier layer and a bottom buffer layer of the quantum well.

Abstract: The present invention is to provide a “fabricating method for quantum dot active layer of LED by nano-lithography” for fabricating out a new active layer of LED of nano quantum dot structure in more miniature manner than that of the current fabricating facilities to have high quality LED with features in longer light wavelength, brighter luminance and lower forward bias voltage by directly using the current fabricating facilities without any alteration or redesign of the precision.

Abstract: A semiconductor fabrication process includes forming a gate dielectric layer (120) overlying a substrate (101) that includes a III-V semiconductor compound. The gate dielectric layer is patterned to produce a gate dielectric structure (121) that has a substantially vertical sidewall (127), e.g., a slope of approximately 45° to 90°. A metal contact structure (130) is formed overlying the wafer substrate. The contact structure is laterally displaced from the gate dielectric structure sufficiently to define a gap (133) between the two. The wafer (100) is heat treated, which causes migration of at least one of the metal elements to form an alloy region (137) in the underlying wafer substrate. The alloy region underlies the contact structure and extends across all or a portion of the wafer substrate underlying the gap. An insulative or dielectric capping layer (140,150) is then formed overlying the wafer and covering the portion of the substrate exposed by the gap.

Abstract: The present invention aims to suppress the diffusion of p-type impurities (typically magnesium), included in a semiconductor region of a III-V compound semiconductor, into an adjoining different semiconductor region. A semiconductor device 10 of the present invention comprises a first semiconductor region 28 of gallium nitride (GaN) including p-type impurities that consist of magnesium, a second semiconductor region 34 of gallium nitride, and an impurity diffusion suppression layer 32 of silicon oxide (SiO2) located between the first semiconductor region 28 and the second semiconductor region 34.

Abstract: The method of the invention for producing a group III-V semiconductor device includes forming, on a base, a plurality of semiconductor devices isolated from one another, each semiconductor device having at least an n-layer proximal to the base, and a p-layer distal to the base, and having a p-electrode formed on the top surface of the p-layer, and a first low-melting-point metal diffusion preventing layer, the low-melting-point metal diffusion preventing layer being formed on the top surface of the p-electrode; forming, from a dielectric material, a side-surface protective film so as to cover a side surface of each semiconductor device; bonding the semiconductor device to a conductive support substrate via a low-melting-point metal layer; and removing the base through the laser lift-off process.