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: In one embodiment, an apparatus includes a first gas distribution assembly that includes a first gas passage for introducing a first process gas into a second gas passage that introduces the first process gas into a processing chamber and a second gas distribution assembly that includes a third gas passage for introducing a second process gas into a fourth gas passage that introduces the second process gas into the processing chamber. The first and second gas distribution assemblies are each adapted to be coupled to at least one chamber wall of the processing chamber. The first gas passage is shaped as a first ring positioned within the processing chamber above the second gas passage that is shaped as a second ring positioned within the processing chamber. The gas distribution assemblies may be designed to have complementary characteristic radial film growth rate profiles.

Abstract: Methods are disclosed for growing group III-nitride semiconductor compounds with advanced buffer layer technique. In an embodiment, a method includes providing a suitable substrate in a processing chamber of a hydride vapor phase epitaxy processing system. The method includes forming an AlN buffer layer by flowing an ammonia gas into a growth zone of the processing chamber, flowing an aluminum halide containing precursor to the growth zone and at the same time flowing additional hydrogen halide or halogen gas into the growth zone of the processing chamber. The additional hydrogen halide or halogen gas that is flowed into the growth zone during buffer layer deposition suppresses homogeneous AlN particle formation. The hydrogen halide or halogen gas may continue flowing for a time period while the flow of the aluminum halide containing precursor is turned off.

Abstract: Embodiments of the present disclosure relate to methods for pretreatment of substrates and group III-nitride layers for manufacturing devices such as light emitting diodes (LEDs), laser diodes (LDs) or power electronic devices. One embodiment of the present disclosure provides a method including providing one or more substrates having an aluminum containing surface in a processing chamber and exposing a surface of each of the one or more substrates having an aluminum containing surface to a pretreatment gas mixture to form a pretreated surface. The pretreatment gas mixture includes ammonia (NH3), an aluminum halide gas (e.g., AlCl3, AlCl) and an etchant containing gas that includes a halogen gas (e.g., Cl2) or hydrogen halide gas (e.g., HCl).

Abstract: Methods are disclosed for growing high crystal quality group III-nitride epitaxial layers with advanced multiple buffer layer techniques. In an embodiment, a method includes forming group III-nitride buffer layers that contain aluminum on suitable substrate in a processing chamber of a hydride vapor phase epitaxy processing system. A hydrogen halide or halogen gas is flowing into the growth zone during deposition of buffer layers to suppress homogeneous particle formation. Some combinations of low temperature buffers that contain aluminum (e.g., AlN, AlGaN) and high temperature buffers that contain aluminum (e.g., AlN, AlGaN) may be used to improve crystal quality and morphology of subsequently grown group III-nitride epitaxial layers. The buffer may be deposited on the substrate, or on the surface of another buffer. The additional buffer layers may be added as interlayers in group III-nitride layers (e.g., GaN, AlGaN, AlN).

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: 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: 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: Described herein are exemplary apparatuses having multiple gas distribution assemblies in accordance with one embodiment. In one embodiment, the apparatus includes two or more gas distribution assemblies. Each gas distribution assembly has orifices through which at least one process gas is introduced into a processing chamber. The two or more gas distribution assemblies may be designed to have complementary characteristic radial film growth rate profiles.

Abstract: Embodiments of the present invention generally relate to a hydride vapor phase epitaxy (HVPE) apparatus that utilizes a high temperature gas distribution device and plasma generation to form an activated precursor gas used to rapidly form a high quality compound nitride layer on a surface of a substrate. In one embodiment, plasma is formed from a nitrogen containing precursor within a gas distribution device prior to injection into a processing region of the HVPE apparatus. In another embodiment, plasma is formed from a nitrogen containing precursor within the processing region by using the gas distribution device as an electrode for forming the plasma in the processing region. In each embodiment, a second precursor gas may be separately introduced into the processing region of the HVPE apparatus through the gas distribution device without mixing with the nitrogen containing precursor prior to entering the processing region.

Abstract: Embodiments of the invention disclosed herein generally relate to a hydride vapor phase epitaxy (HVPE) deposition chamber that utilizes a plasma generation apparatus to form an activated precursor gas that is used to rapidly form a high quality compound nitride layer on a surface of a substrate. In one embodiment, the plasma generation apparatus is used to create a desirable group-III metal halide precursor gas that can enhance the deposition reaction kinetics, and thus reduce the processing time and improve the film quality of a formed group-III metal nitride layer. In addition, the chamber may be equipped with a separate nitrogen containing precursor activated species generator to enhance the activity of the delivered nitrogen precursor gases.

Abstract: Apparatus and systems are disclosed for providing a protective material for a showerhead of a processing system. In an embodiment, a processing system includes a processing chamber for processing substrates and a showerhead having a diffuser plate for distributing processing gases to the processing chamber. The diffuser plate may include a protective material to protect the showerhead from processing gases. The diffuser plate may be formed with tungsten or tungsten coated with a tantalum alloy and tantalum.

Abstract: Methods are disclosed for growing group III-nitride semiconductor compounds with advanced buffer layer technique. In an embodiment, a method includes providing a suitable substrate in a processing chamber of a hydride vapor phase epitaxy processing system. The method includes forming an AlN buffer layer by flowing an ammonia gas into a growth zone of the processing chamber, flowing an aluminum halide containing precursor to the growth zone and at the same time flowing additional hydrogen halide or halogen gas into the growth zone of the processing chamber. The additional hydrogen halide or halogen gas that is flowed into the growth zone during buffer layer deposition suppresses homogeneous AlN particle formation. The hydrogen halide or halogen gas may continue flowing for a time period while the flow of the aluminum halide containing precursor is turned off.

Abstract: Methods are disclosed for growing high crystal quality group III-nitride epitaxial layers with advanced multiple buffer layer techniques. In an embodiment, a method includes forming group III-nitride buffer layers that contain aluminum on suitable substrate in a processing chamber of a hydride vapor phase epitaxy processing system. A hydrogen halide or halogen gas is flowing into the growth zone during deposition of buffer layers to suppress homogeneous particle formation. Some combinations of low temperature buffers that contain aluminum (e.g., AlN, AlGaN) and high temperature buffers that contain aluminum (e.g., AlN, AlGaN) may be used to improve crystal quality and morphology of subsequently grown group III-nitride epitaxial layers. The buffer may be deposited on the substrate, or on the surface of another buffer. The additional buffer layers may be added as interlayers in group III-nitride layers (e.g., GaN, AlGaN, AlN).

Abstract: Embodiments of the present disclosure relate to methods for pretreatment of substrates and group III-nitride layers for manufacturing devices such as light emitting diodes (LEDs), laser diodes (LDs) or power electronic devices. One embodiment of the present disclosure provides a method including providing one or more substrates having an aluminum containing surface in a processing chamber and exposing a surface of each of the one or more substrates having an aluminum containing surface to a pretreatment gas mixture to form a pretreated surface. The pretreatment gas mixture includes ammonia (NH3), an aluminum halide gas (e.g., AlCl3, AlCl) and an etchant containing gas that includes a halogen gas (e.g., Cl2) or hydrogen halide gas (e.g., HCl).

Abstract: One embodiment of a quantum well structure comprises an active region including active layers that comprise quantum wells and barrier layers wherein some or all of the active layers are p type doped. P type doping some or all of the active layers improves the quantum efficiency of III-V compound semiconductor light emitting diodes by locating the position of the P-N junction in the active region of the device thereby enabling the dominant radiative recombination to occur within the active region. In one embodiment, the quantum well structure is fabricated in a cluster tool having a hydride vapor phase epitaxial (HVPE) deposition chamber with a eutectic source alloy. In one embodiment, the indium gallium nitride (InGaN) layer and the magnesium doped gallium nitride (Mg—GaN) or magnesium doped aluminum gallium nitride (Mg—AlGaN) layer are grown in separate chambers by a cluster tool to avoid indium and magnesium cross contamination.

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 pretreating 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: 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: 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.