Abstract: A spalling process can be employed to generate a fracture at a predetermined depth within a high quality crystalline nitride substrate, such as a bulk GaN substrate. A first crystalline conductive film layer can be separated, along the line of fracture, from the crystalline nitride substrate and subsequently bonded to a layered stack including a traditional lower-cost substrate. If the spalled surface of the first crystalline conductive film layer is exposed in the resulting structure, the structure can act as a substrate on which high quality GaN-based devices can be grown.

Abstract: A stressor layer is applied to a semiconducting stack in order to separate the semiconducting stack at a predetermined depth. Tensile force is applied to the stressor layer, fracturing the semiconducting stack at the predetermined depth and allowing the resulting upper portion of the semiconducting stack to be used in manufacturing a semiconducting end-product (e.g., a light-emitting diode). The resulting lower portion of the semiconducting stack may be reused to grow a new semiconducting stack thereon.

Abstract: A spalling process can be employed to generate a fracture at a predetermined depth within a high quality crystalline nitride substrate, such as a bulk GaN substrate. A first crystalline conductive film layer can be separated, along the line of fracture, from the crystalline nitride substrate and subsequently bonded to a layered stack including a traditional lower-cost substrate. If the spalled surface of the first crystalline conductive film layer is exposed in the resulting structure, the structure can act as a substrate on which high quality GaN-based devices can be grown.

Abstract: A stressor layer is applied to a semiconducting stack in order to separate the semiconducting stack at a predetermined depth. Tensile force is applied to the stressor layer, fracturing the semiconducting stack at the predetermined depth and allowing the resulting upper portion of the semiconducting stack to be used in manufacturing a semiconducting end-product (e.g., a light-emitting diode). The resulting lower portion of the semiconducting stack may be reused to grow a new semiconducting stack thereon.

Abstract: Methods and apparatus for reducing autodoping and backside defects on a substrate during epitaxial deposition processes are provided herein. In some embodiments, an apparatus for reducing autodoping and backside defects on a substrate includes a substrate support ring having a substrate holder structure configured to support the substrate in a position for processing along an edge defined by the backside of the substrate and a sidewall of the substrate or along a plurality of discrete points on or proximate to the edge; and a spacer ring for positioning the substrate support ring above a susceptor plate to define a substrate gap region between the susceptor plate and the backside of the substrate, the spacer ring comprising a plurality of openings formed therethrough that facilitate passage of a gas into and out of the substrate gap region.

Abstract: According to one aspect of the invention, an apparatus for reducing auto-doping of the front side of a substrate and reducing defects on the backside of the substrate during an epitaxial deposition process for forming an epitaxial layer on the front side of the substrate comprising: a means for forming a wafer gap region between the backside of the substrate and a susceptor plate, having an adjustable thickness; a means for ventilating auto-dopants out of the wafer gap region with a flow of inert gas, while inhibiting or prohibiting the flow of inert gas over the front side of the substrate; and a means for flowing reactant gases over the surface of the front side of the substrate, while inhibiting or prohibiting the flow of reactant gases near the surface of the backside of the substrate.

Abstract: A system for monitoring a process inside a high temperature semiconductor process chamber by capturing images is disclosed. Images are captured through a borescope by a camera. The borescope is protected from high temperatures by a reflective sheath and an Infrared (IR) cut-off filter. Images can be viewed on a monitor and can be recorded by a video recording device. Images can also be processed by a machine vision system. The system can monitor the susceptor and a substrate on the susceptor and surrounding structures. Deviations from preferred geometries of the substrate and deviations from preferred positions of susceptor and the substrate can be detected. Actions based on the detections of deviations can be taken to improve the performance of the process. Illumination of a substrate by a laser for detecting deviations in substrate geometry and position is also disclosed.

Abstract: Methods and apparatus for providing constant emissivity of the backside of susceptors are described. Provided is a method comprising: providing a susceptor in a deposition chamber, the susceptor comprising a susceptor plate and a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof, the layer being stable in the presence of the reactive process gases; and locating the wafer on a support surface of the susceptor plate. The method can further comprise selectively depositing an epitaxial layer or a non-epitaxial layer on a surface of the wafer. The method can also further comprise selectively etching to maintain the oxide, nitride, oxynitride, or combinations thereof layer.

Abstract: A dual-beam laser cutting system uses laser beam polarization to output two identical laser beams. The dual identical laser beams are spaced appropriately to simultaneously cut a water thus increasing the laser cutting system's throughput as compared to a single-laser cutting system. In one implementation, the dual-beam laser cutting system 100 utilizes a beam expander 220, two half-wave plates 224, 238, a polarizing beam splitter 228, a mirror 236, and two lenses 234, 242 to provide two identical laser beams 202, 204 from a single laser source 214. The identical laser beams 202, 204 are tuned to have the same power, cross-sectional diameter, and polarization direction. One of the half-wave plates 224 is rotated to yield laser beams with the same power. The other half-wave plate 238 is rotated to yield laser beams with the same polarization direction.

Abstract: A film formation system 10 includes a processing chamber 15 bounded by sidewalls 18 and a top cover 11. In one embodiment, a susceptor 16 is rotatably disposed in the system 10, and overlaps with a first peripheral member 205 disposed around the sidewalls 18. A radiant heating system 313 is disposed under the susceptor 305 to heat the substrate 19. In another embodiment, the top cover 11 has equally spaced pyrometers 58 for measuring the temperature of the substrate 19 across a number of zones. The temperature of the substrate 19 is obtained from pyrometric data from the pyrometers 58.

Abstract: Methods and apparatus for providing constant emissivity of the backside of susceptors are described. Provided is a method comprising: providing a susceptor in a deposition chamber, the susceptor comprising a susceptor plate and a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof, the layer being stable in the presence of the reactive process gases; and locating the wafer on a support surface of the susceptor plate. The method can further comprise selectively depositing an epitaxial layer or a non-epitaxial layer on a surface of the wafer. The method can also further comprise selectively etching to maintain the oxide, nitride, oxynitride, or combinations thereof layer.

Abstract: Methods and apparatus for providing constant emissivity of the backside of susceptors are provided. Provided is a susceptor comprising: a susceptor plate having a surface for supporting a wafer and a backside surface opposite the wafer supporting surface; a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof located on the backside surface of the susceptor plate, the layer being stable in the presence of a reactive process gas. The layer comprises, for example, silicon dioxide, silicon nitride, silicon oxynitride, or combinations thereof. Also provided is a method comprising: providing a susceptor in a deposition chamber, the susceptor comprising a susceptor plate and a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof, the layer being stable in the presence of the reactive process gases; locating the wafer on a support surface of the susceptor plate.

Abstract: A dual-beam laser cutting system uses laser beam polarization to output two identical laser beams. The dual identical laser beams are spaced appropriately to simultaneously cut a water thus increasing the laser cutting system's throughput as compared to a single-laser cutting system. In one implementation, the dual-beam laser cutting system 100 utilizes a beam expander 220, two half-wave plates 224, 238, a polarizing beam splitter 228, a mirror 236, and two lenses 234, 242 to provide two identical laser beams 202, 204 from a single laser source 214. The identical laser beams 202, 204 are tuned to have the same power, cross-sectional diameter, and polarization direction. One of the half-wave plates 224 is rotated to yield laser beams with the same power. The other half-wave plate 238 is rotated to yield laser beams with the same polarization direction.

Abstract: A film formation system 10 has a processing chamber 15 bounded by sidewalls 18 and a top cover 11. In one embodiment, the top cover 11 has a reflective surface 13 for reflecting radiant energy back onto a substrate 19, pyrometers 405 for measuring the temperature of the substrate 19 across a number of zones, and at least one emissometer 410 for measuring the actual emissivity of the substrate 19. In another embodiment, a radiant heating system 313 is disposed under the substrate support 16. The temperature of the substrate 19 is obtained from pyrometric data from the pyrometers 405, and the emissometer 410.

Abstract: A system for monitoring a process inside a high temperature semiconductor process chamber by capturing images is disclosed. Images are captured through a borescope by a camera. The borescope is protected from high temperatures by a reflective sheath and an Infrared (IR) cur-off filter. Images can be viewed on a monitor and can be recorded by a video recording device. Images can also be processed by a machine vision system. The system can monitor the susceptor and a substrate on the susceptor and surrounding structures. Deviations from preferred geometries of the substrate and deviations from preferred positions of susceptor and the substrate can be detected. Actions based on the detections of deviations can be taken to improve the performance of the process. Illumination of a substrate by a laser for detecting deviations in substrate geometry and position is also disclosed.

Abstract: The present invention generally is a method for forming a high-k dielectric layer, comprising depositing a hafnium compound by atomic layer deposition to a substrate, comprising, delivering a hafnium precursor to a surface of the substrate, reacting the hafnium precursor and forming a hafnium containing layer to the surface, delivering a nitrogen precursor to the hafnium containing layer, forming at least one hafnium nitrogen bond and depositing the hafnium compound to the surface.

Abstract: Methods and apparatus for providing constant emissivity of the backside of susceptors are provided. Provided is a susceptor comprising: a susceptor plate having a surface for supporting a wafer and a backside surface opposite the wafer supporting surface; a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof located on the backside surface of the susceptor plate, the layer being stable in the presence of a reactive process gas. The layer comprises, for example, silicon dioxide, silicon nitride, silicon oxynitride, or combinations thereof. Also provided is a method comprising: providing a susceptor in a deposition chamber, the susceptor comprising a susceptor plate and a layer comprising an oxide, a nitride, an oxynitride, or combinations thereof, the layer being stable in the presence of the reactive process gases; locating the wafer on a support surface of the susceptor plate.

Abstract: The present invention provides methods and apparatus for processing semiconductor substrates. Particularly, the present invention provides a modular processing cell to be used in a cluster tool. The modular semiconductor processing cell of the present invention comprises a chamber having an inject cap, a gas panel module configured to supply one or more processing gas to the chamber through the inject cap, wherein the gas panel module is position adjacent the inject cap. The processing cell further comprises a lamp module positioned below the chamber. The lamp module comprises a plurality of vertically oriented lamps.

Abstract: Methods and apparatus for reducing autodoping and backside defects on a substrate during epitaxial deposition processes are provided herein. In some embodiments, an apparatus for reducing autodoping and backside defects on a substrate includes a substrate support ring having a substrate holder structure configured to support the substrate in a position for processing along an edge defined by the backside of the substrate and a sidewall of the substrate or along a plurality of discrete points on or proximate to the edge; and a spacer ring for positioning the substrate support ring above a susceptor plate to define a substrate gap region between the susceptor plate and the backside of the substrate, the spacer ring comprising a plurality of openings formed therethrough that facilitate passage of a gas into and out of the substrate gap region.

Abstract: According to one aspect of the invention, an apparatus for reducing auto-doping of the front side of a substrate and reducing defects on the backside of the substrate during an epitaxial deposition process for forming an epitaxial layer on the front side of the substrate comprising: a means for forming a wafer gap region between the backside of the substrate and a susceptor plate, having an adjustable thickness; a means for ventilating auto-dopants out of the wafer gap region with a flow of inert gas, while inhibiting or prohibiting the flow of inert gas over the front side of the substrate; and a means for flowing reactant gases over the surface of the front side of the substrate, while inhibiting or prohibiting the flow of reactant gases near the surface of the backside of the substrate.