Abstract: In one aspect, a system for depositing a layer on a substrate is provided. The system includes a processing chamber, a gas injecting port, a gas distribution plate, and a plug. The gas injecting port is disposed upstream from the processing chamber. The gas distribution plate is disposed between the gas injecting port and the processing chamber, and includes an elongate planar body and an array of holes therein. The plug is sized to be received within one of the holes, and includes an orifice therethrough for permitting the passage of gas. The plug is capable of being removably secured to the gas distribution plate within one of the holes.

Abstract: Methods and systems for use in detecting an air pocket in a single crystal material are described. One example method includes providing a matrix including a plurality of data units, the plurality of data units including image data related to a region of interest of the single crystal material; defining a first half and a second half of the matrix based on a first axis passing through the center of the matrix; determining, by a processor, a difference between each data unit of the first half and a corresponding data unit of the second half; calculating, by the processor, a first index value based on the determined differences; and identifying an air pocket within the single crystal material based on the first index value and a predetermined threshold.

Abstract: A method of preparing a monocrystalline donor substrate, the method comprising (a) implanting helium ions through the front surface of the monocrystalline donor substrate to an average depth D1 as measured from the front surface toward the central plane; (b) implanting hydrogen ions through the front surface of the monocrystalline donor substrate to an average depth D2 as measured from the front surface toward the central plane; and (c) annealing the monocrystalline donor substrate at a temperature sufficient to form a cleave plane in the monocrystalline donor substrate. The average depth D1 and the average depth D2 are within about 1000 angstroms.

Abstract: Apparatus and methods for mechanically cleaving a bonded wafer structure are disclosed. The apparatus and methods involve clamps that grip the bonded wafer structure and are actuated to cause the bonded structure to cleave.

Abstract: Methods for cleaning semiconductor substrates with cleaning baths including ammonium hydroxide, hydrogen peroxide and a non-ionic surfactant are disclosed. The methods may result in reduced re-adhesion of released particles during cleaning which produces cleaner substrates.

Abstract: A method of preparing a high resistivity single crystal semiconductor handle wafer comprising implanting He ions through a front surface of the high resistivity single crystal semiconductor handle wafer, which is followed by an anneal sufficient to form a nanocavity layer in the damage region formed by He ion implantation. The anneal may be prior to or concurrent with thermal oxidation to prepare a front oxidized surface layer.

Abstract: A method for reducing light point defects of a semiconductor-on-insulator structure and a method for reducing the surface roughness of a semiconductor-on-insulator structure are disclosed. The methods can include a combination of thermally annealing the structure followed by a non-contact smoothing process.

Abstract: A method of polishing a wafer is disclosed that includes determining a removal profile. The wafer is measured to determine a starting wafer profile and then the wafer is polished. The wafer is again measured after being polished to determine a polished wafer profile. The starting wafer profile and the polished wafer profile are compared to each other to determine the removal profile by computing the amount and shape of material removed from the first wafer during polishing.

Abstract: A platen for polishing a surface of a wafer has a reaction plate, a polishing plate, and a bladder. The reaction plate has a top and bottom surface, and defines a longitudinal axis. The polishing plate is positioned coaxially with the reaction plate. The polishing plate has a second top surface and a second bottom surface. The second top surface is adjacent to the bottom surface of the reaction plate. The bladder is coaxially located along a radially outer portion of either the top or bottom surface of the reaction plate. The bladder is connected with the polishing plate and able to expand to deform the polishing plate with respect to the bottom surface of the reaction plate.

Abstract: Apparatus and methods for mechanically cleaving a bonded wafer structure are disclosed. The apparatus and methods involve clamps that grip the bonded wafer structure and are actuated to cause the bonded structure to cleave.

Abstract: Apparatus and methods for mechanically cleaving a bonded wafer structure are disclosed. The apparatus and methods involve clamps that grip the bonded wafer structure and are actuated to cause the bonded structure to cleave.

Abstract: Processes for the treatment of silicon wafers to form a high density non-uniform distribution of oxygen precipitate nuclei therein such that, upon being subjected to the heat treatment cycles of essentially any arbitrary electronic device manufacturing process, the wafers form oxygen precipitates in the bulk and a precipitate-free zone near the surface are disclosed. The processes involve activation of inactive oxygen precipitate nuclei by performing heat treatments between about 400° C. and about 600° C. for at least about 1 hour.

Abstract: A system for depositing a layer on a substrate includes a processing chamber, a gas injecting port for introducing gas into the system, a gas distribution plate disposed between the gas injecting port and the processing chamber, the gas distribution plate including holes therein, and an inject insert liner assembly received within the system adjacent to the gas distribution plate and upstream from the processing chamber. The inject insert liner assembly defines gas flow channels therein extending along a lengthwise direction of the system, wherein each channel includes an inlet and an outlet, and at least one channel is tapered along the lengthwise direction of the system in at least one of a vertical or horizontal direction. The inject insert liner assembly has the same number of gas flow channels as the number of holes in the gas distribution plate.

Abstract: A method for preparing a semiconductor structure for use in the manufacture of three dimensional transistors, the structure comprising a silicon substrate and an epitaxial layer, the epitaxial layer comprising an endpoint detection epitaxial region comprising an endpoint detection impurity selected from the group consisting of carbon, germanium, or a combination.

Abstract: A method of fabricating a semiconductor processing device includes providing a susceptor including a substantially cylindrical body portion having opposing upper and lower surfaces. The body portion has a diameter larger than a wafer diameter. The method also includes providing a set of holes circumferentially disposed at a first susceptor diameter, the set of holes being evenly spaced with respect to adjacent holes and extending through the upper and lower surfaces in an area. The first susceptor diameter is larger than the wafer diameter, and holes are omitted along the first diameter in a set of predetermined orientations.

Abstract: The invention generally related to a method for preparing a layer of graphene directly on the surface of a semiconductor substrate. The method includes forming a carbon-containing layer on a front surface of a semiconductor substrate and depositing a metal film on the carbon layer. A thermal cycle degrades the carbon-containing layer, which forms graphene directly upon the semiconductor substrate upon cooling. In some embodiments, the carbon source is a carbon-containing gas, and the thermal cycle causes diffusion of carbon atoms into the metal film, which, upon cooling, segregate and precipitate into a layer of graphene directly on the semiconductor substrate.

Abstract: This invention generally relates to an epitaxial silicon semiconductor wafer with increased thermal conductivity to transfer heat away from a device layer, while also having resistance to common failure mechanisms, such as latch-up failures and radiation event failures. The semiconductor wafer comprises a lightly-doped device layer, a highly-doped protective layer, and a lightly-doped substrate. The invention is also directed to a process for forming such an epitaxial silicon wafer.

Abstract: Methods for producing crucibles for holding molten material that contain a reduced amount of gas pockets are disclosed. The methods may involve use of molten silica that may be outgassed prior to or during formation of the crucible. Crucibles produced from such methods and ingots and wafers that are produced from crucibles with a reduced amount of gas pockets are also disclosed.

Abstract: Methods and systems are disclosed for performing a passivation process on a silicon-on-insulator wafer in a chamber in which the wafer is cleaved. A bonded wafer pair is cleaved within the chamber to form the silicon-on-insulator (SOI) wafer. A cleaved surface of the SOI wafer is then passivated in-situ by exposing the cleaved surface to a passivating substance. This exposure to a passivating substance results in the formation of a thin layer of oxide on the cleaved surface. The silicon-on-insulator wafer is then removed from the chamber. In other embodiments, the silicon-on-insulator wafer is first transferred to an adjoining chamber where the wafer is then passivated. The wafer is transferred to the adjoining chamber without exposing the wafer to the atmosphere outside the chambers.

Abstract: A method is provided for preparing multilayer semiconductor structures, such as silicon-on-insulator wafers, having reduced warp and bow. Reduced warp multilayer semiconductor structures are prepared by forming a dielectric structure on the exterior surfaces of a bonded pair of a semiconductor device substrate and a semiconductor handle substrate having an intervening dielectric layer therein. Forming a dielectric layer on the exterior surfaces of the bonded pair offsets stresses that may occur within the bulk of the semiconductor handle substrate due to thermal mismatch between the semiconductor material and the intervening dielectric layer as the structure cools from process temperatures to room temperatures.