Abstract: Techniques for crack-free growth of GaN, and related, films on larger-size substrates via spatially confined epitaxy are described.

Abstract: A method for reclamation of scrap materials during the formation of Group III-V materials by metal-organic chemical vapor deposition (MOCVD) processes and/or hydride vapor phase epitaxial (HVPE) processes is provided. More specifically, embodiments described herein generally relate to methods for repairing or replacing defective films or layers during the formation of devices formed by these materials. By periodic testing of the layers during the formation process, low-quality layers that may result in low-quality or defective devices may be detected prior to completion of the device. These low-quality layers may be partially or completely removed and redeposited to reclaim the substrate and any remaining high-quality layers that were previously deposited under the low-quality layer.

Abstract: Nano-spherical group III-nitride materials and methods of forming nano-spherical group III-nitride materials are described. Also described is a 1-dimensional LED or similar device formed from a single nano-rod of a nano-spherical group III-nitride material.

Abstract: A method and apparatus for removing deposition products from internal surfaces of a processing chamber, and for preventing or slowing growth of such deposition products. A halogen containing gas is provided to the chamber to etch away deposition products. A halogen scavenging gas is provided to the chamber to remove any residual halogen. The halogen scavenging gas is generally activated by exposure to electromagnetic energy, either inside the processing chamber by thermal energy, or in a remote chamber by electric field, UV, or microwave. A deposition precursor may be added to the halogen scavenging gas to form a deposition resistant film on the internal surfaces of the chamber. Additionally, or alternately, a deposition resistant film may be formed by sputtering a deposition resistant metal onto internal components of the processing chamber in a PVD process.

Abstract: A method for in-situ cleaning of a deposition system is disclosed. The method includes providing a deposition system with portions of the deposition system deposited with at least a group III element or a compound of a group III element. Halogen containing fluid is introduced into the deposition system. The halogen containing fluid is permitted to react with the group III element to form a halide. The halide in solid state is converted to a gaseous state. The halide in gaseous state is purged out of the deposition system.

Abstract: One embodiment of the forming a nanocrystalline diamond-structured carbon layer on a silicon carbide layer comprises providing a silicon carbide layer in a reaction chamber and exposing the silicon carbide layer to a chlorine containing gas for an exposure time period to form a nanocrystalline diamond-structured carbon layer from the silicon carbide layer.

Abstract: Disclosed herein is an article comprising a substrate; an interlayer comprising aluminum nitride, gallium nitride, boron nitride, indium nitride or a solid solution of aluminum nitride, gallium nitride, boron nitride and/or indium nitride; the interlayer being directly disposed upon the substrate and in contact with the substrate; where the interlayer comprises a columnar film and/or nanorods and/or nanotubes; and a group-III nitride layer disposed upon the interlayer; where the group-III nitride layer completely covers a surface of the interlayer that is opposed to a surface in contact with the substrate; the group-III nitride layer being free from cracks.

Abstract: The present invention generally provides a method and apparatus for cleaning a showerhead of a deposition chamber, such as a metal organic chemical vapor deposition (MOCVD) chamber. In one embodiment, the showerhead is cleaned without exposing the chamber to the atmosphere outside of the chamber (i.e., in situ cleaning). In one embodiment, flow of liquid coolant through a cooling system that is in fluid communication with the showerhead is redirected to bypass the showerhead, and the liquid coolant is drained from the showerhead. In one embodiment, any remaining coolant is flushed from the showerhead via a pressurized gas source. In one embodiment, the showerhead is then heated to an appropriate cleaning temperature. In one embodiment, the flow of liquid coolant from the cooling system is then redirected to the showerhead and the system is adjusted for continued processing. Thus, the entire showerhead cleaning process is performed with minimal change to the flow of coolant through the cooling system.

Abstract: Embodiments described herein generally relate to apparatus and methods for forming Group III-V materials by metal-organic chemical vapor deposition (MOCVD) processes and hydride vapor phase epitaxial (HVPE) processes. In one embodiment, a method for fabricating a nitrogen-face (N-face) polarity compound nitride semiconductor device is provided. The method comprises depositing a nitrogen containing buffer layer having N-face polarity over one or more substrates using a metal organic chemical vapor deposition (MOCVD) process to form one or more substrates having N-face polarity and depositing a gallium nitride (GaN) layer over the nitrogen containing buffer layer using a hydride vapor phase epitaxial (HVPE) deposition process, wherein the nitrogen containing buffer layer and the GaN layer are formed without breaking vacuum and exposing the one or more substrates to atmosphere.

Abstract: One embodiment of fabricating a p-down light emitting diode (LED) structure comprises depositing a high crystal quality p type contact layer, depositing an active region on top of the p type contact layer, and depositing an n type contact layer on top of the active region using a hydride vapor phase epitaxy (HVPE) process. The high crystal quality p type contact layer is deposited at high temperature to ensure the high crystal quality of the p type film. The n type contact layer is formed on top of the active region in a HVPE chamber at a low temperature to prevent thermal damage to the quantum wells in the active region below the n type contact layer. The processing chamber used to form the p type contact layer is a separate processing chamber than the processing chamber used to form the n type contact layer.

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 of depositing a high quality low defect single crystalline Group III-Nitride film. A patterned substrate having a plurality of features with inclined sidewalls separated by spaces is provided. A Group III-Nitride film is deposited by a hydride vapor phase epitaxy (HVPE) process over the patterned substrate. The HVPE deposition process forms a Group III-Nitride film having a first crystal orientation in the spaces between features and a second different crystal orientation on the inclined sidewalls. The first crystal orientation in the spaces subsequently overgrows the second crystal orientation on the sidewalls and in the process turns over and terminates treading dislocations formed in the first crystal orientation.

Abstract: A method and apparatus is provided for preparing a substrate for forming electronic devices incorporating III/V compound semiconductors. Elemental halogen gases, hydrogen halide gases, or other halogen or halide gases, are contacted with liquid or solid group III metals to form precursors which are reacted with nitrogen sources to deposit a nitride buffer layer on the substrate. The buffer layer, which may be a transition layer, may incorporate more than one group III metal, and may be deposited with amorphous or crystalline morphology. An amorphous layer may be partially or fully recrystallized by thermal treatment. Instead of a layer, a plurality of discrete nucleation sites may be formed, whose size, density, and distribution may be controlled. The nitrogen source may include reactive nitrogen compounds as well as active nitrogen from a remote plasma source. The composition of the buffer or transition layer may also vary with depth according to a desired profile.

Abstract: In one embodiment a method for fabricating a compound nitride semiconductor device comprising positioning one or more substrates on a susceptor in a processing region of a metal organic chemical vapor deposition (MOCVD) chamber comprising a showerhead, depositing a gallium nitride layer over the substrate with a thermal chemical-vapor-deposition process within the MOCVD chamber by flowing a first gallium containing precursor and a first nitrogen containing precursor through the showerhead into the MOCVD chamber, removing the one or more substrates from the MOCVD chamber without exposing the one or more substrates to atmosphere, flowing a chlorine gas into the processing chamber to remove contaminants from the showerhead, transferring the one or more substrates into the MOCVD chamber after removing contaminants from the showerhead, and depositing an InGaN layer over the GaN layer with a thermal chemical-vapor-deposition process within the MOCVD chamber is provided.

Abstract: Embodiments of the present invention relate to apparatus and method for pretreatment of substrates for manufacturing devices such as light emitting diodes (LEDs) or laser diodes (LDs). One embodiment of the present invention comprises pre-treating the aluminum oxide containing substrate by exposing a surface of the aluminum oxide containing substrate to a pretreatment gas mixture, wherein the pretreatment gas mixture comprises ammonia (NH3) and a halogen gas.

Abstract: Embodiments of the present invention generally relate to methods and apparatus for removing unwanted deposition build-up from one more interior surfaces of a substrate processing chamber after a substrate is processed in a chamber to form, for example, Group III-V materials by metal-organic chemical vapor deposition (MOCVD) deposition processes and/or hydride vapor phase epitaxial (HVPE) deposition processes. In one embodiment, a method for removing unwanted deposition build-up from one or more interior surfaces of a substrate processing chamber is provided. The method comprises depositing one or more Group III containing layers over a substrate disposed in the substrate processing chamber, transferring the substrate out of the substrate processing chamber, and pulsing a halogen containing gas into the substrate processing chamber to remove at least a portion of the unwanted deposition build-up from one or more interior surfaces of the substrate processing chamber.

Abstract: Embodiments disclosed herein generally relate to an HVPE chamber. The chamber may have two separate precursor sources coupled thereto to permit two separate layers to be deposited. For example, a gallium source and a separate aluminum source may be coupled to the processing chamber to permit gallium nitride and aluminum nitride to be separately deposited onto a substrate in the same processing chamber. The nitrogen may be introduced to the processing chamber at a separate location from the gallium and the aluminum and at a lower temperature. The different temperatures causes the gases to mix together, react and deposit on the substrate with little or no deposition on the chamber walls.

Abstract: Embodiments disclosed herein generally relate to an HVPE chamber. The chamber may have two separate precursor sources coupled thereto to permit two separate layers to be deposited. For example, a gallium source and a separate aluminum source may be coupled to the processing chamber to permit gallium nitride and aluminum nitride to be separately deposited onto a substrate in the same processing chamber. The nitrogen may be introduced to the processing chamber at a separate location from the gallium and the aluminum and at a lower temperature. The different temperatures causes the gases to mix together, react and deposit on the substrate with little or no deposition on the chamber walls.

Abstract: The present invention generally provides apparatus and methods for forming LED structures. One embodiment of the present invention provides a method for fabricating a compound nitride structure comprising forming a first layer comprising a first group-III element and nitrogen on substrates in a first processing chamber by a hydride vapor phase epitaxial (HVPE) process or a metal organic chemical vapor deposition (MOCVD) process, forming a second layer comprising a second group-III element and nitrogen over the first layer in a second processing chamber by a MOCVD process, and forming a third layer comprising a third group-III element and nitrogen over the second layer by a MOCVD process.

Abstract: A method and apparatus that may be utilized in deposition processes, such as hydride vapor phase epitaxial (HVPE) deposition of metal nitride films, are provided. A first set of passages may introduce a metal containing precursor gas. A second set of passages may provide a nitrogen-containing precursor gas. The first and second sets of passages may be interspersed in an effort to separate the metal containing precursor gas and nitrogen-containing precursor gas until they reach a substrate. An inert gas may also be flowed down through the passages to help keep separation and limit reaction at or near the passages, thereby preventing unwanted deposition on the passages.