Abstract: A substrate carrier that supports a semiconductor substrate in a chemical vapor deposition system that includes a support having a beveled inner top surface including a top surface and a bottom surface. The top surface has a recessed area for receiving at least one substrate for chemical vapor deposition processing. The bottom surface has a beveled edge that forms a conical interface with the beveled inner top surface of the support at a self-locking angle that prevents substrate carrier movement in a vertical direction at a predetermined temperature equal to a maximum operation temperature. A coefficient of thermal expansion of a material forming the substrate carrier is substantially the same as a coefficient of thermal expansion of a material forming the support.

Abstract: A rotating disk reactor for chemical vapor deposition includes a vacuum chamber and a ferrofluid feedthrough comprising an upper and a lower ferrofluid seal that passes a motor shaft into the vacuum chamber. A motor is coupled to the motor shaft and is positioned in an atmospheric region between the upper and the lower ferrofluid seal. A turntable is positioned in the vacuum chamber and is coupled to the motor shaft so that the motor rotates the turntable at a desired rotation rate. A dielectric support is coupled to the turntable so that the turntable rotates the dielectric support when driven by the shaft. A substrate carrier is positioned on the dielectric support in the vacuum chamber for chemical vapor deposition processing. A heater is positioned proximate to the substrate carrier that controls the temperature of the substrate carrier to a desired temperature for chemical vapor deposition.

Abstract: The wafer processing system includes a rotatable wafer support member for supporting a wafer and a plurality of collections trays disposed about a peripheral edge of the wafer support member. The collection trays are arranged in a stacked configuration, each collection tray having an inner wall portion and an outer wall portion that converge to define a trough section for collecting fluid. The system includes a chamber exhaust outlet that is formed in the housing for venting gas from the interior of the housing outside of the collection trays and a chemical exhaust outlet that is formed in the housing for venting gas that flows through the collection chamber to the chemical exhaust outlet. The chemical exhaust outlet is fluidly isolated from the chamber exhaust outlet.

Abstract: Methods of forming 2D metal chalcogenide films using laser-assisted atomic layer deposition are disclosed. A direct-growth method includes: adhering a layer of metal-bearing molecules to the surface of a heated substrate; then reacting the layer of metal-bearing molecules with a chalcogenide-bearing radicalized precursor gas delivered using a plasma to form an amorphous 2D film of the metal chalcogenide; then laser annealing the amorphous 2D film to form a crystalline 2D film of the metal chalcogenide, which can have the form MX or MX2, where M is a metal and X is the chalcogenide. An indirect growth method that includes forming an MO3 film is also disclosed.

Abstract: Methods disclosed herein include scanning a focus spot formed by a laser beam over either a metal layer or IC structures that include a metal and a non-metal. The focus spot is scanned over a scan path that includes scan path segments that partially overlap. The focus spot has an irradiance and a dwell time selected to locally melt the metal layer or locally melt the metal of the IC structures without melting the non-metal. This results in rapid melting and recrystallization of the metal, which decreases the resistivity of the metal and results in improved performance of the IC chips being fabricated. Also disclosed is an example laser melt system for carrying out methods disclosed herein is also disclosed.

Abstract: A chemical vapor deposition or atomic layer deposition system includes a gas concentration sensor for determining the quantity of precursor gases admitted thereto. The gas concentration sensor can include a transmitter and a receiver for transmitting an acoustic signal across a chamber. In embodiments, the transmitter and receiver are designed to increase transmitted signal while reducing transmitted noise, facilitating use of the gas concentration sensor at low pressure and high temperature.

Abstract: An arrangement of two shutters radially outward from an injector block and a susceptor onto which a wafer carrier is removably mounted are configured to provide a flowpath through a reactor chamber that does not exhibit a vortex, thereby reducing or eliminating buildup on the inside of the reactor chamber and facilitating large temperature gradient between the injector block and the wafer carrier. This can be accomplished by introduction of a purge gas flow at a radially inner wall of an upper shutter, and in some embodiments the purge gas can have a different chemical composition than the precursor gas used to grow desired epitaxial structures on the wafer carrier.

Abstract: Filter elements for gaseous fluid (e.g., air) filtration for wafer processing systems. The filter elements have a pleat ratio of no greater than 7, where the pleat ratio is the number of pleats per mean diameter of the filter. By having a pleat ratio no greater than 7, and in some implementations also greater than 5, the filter is optimized for wafer processing systems and methods. This pleat ratio optimizes the spacing between pleats, thus balancing filtration media area against effective area, such as what might be lost due to contaminant bridging.

Abstract: A self-centering wafer carrier system for a chemical vapor deposition (CVD) reactor includes a wafer carrier comprising an edge. The wafer carrier at least partially supports a wafer for CVD processing. A rotating tube comprises an edge that supports the wafer carrier during processing. An edge geometry of the wafer carrier and an edge geometry of the rotating tube being chosen to provide a coincident alignment of a central axis of the wafer carrier and a rotation axis of the rotating tube during process at a desired process temperature.

Abstract: A self-centering wafer carrier system for a chemical vapor deposition (CVD) reactor includes a wafer carrier comprising an edge. The wafer carrier at least partially supports a wafer for CVD processing. A rotating tube comprises an edge that supports the wafer carrier during processing. An edge geometry of the wafer carrier and an edge geometry of the rotating tube being chosen to provide a coincident alignment of a central axis of the wafer carrier and a rotation axis of the rotating tube during process at a desired process temperature.

Abstract: Pattern-multiplication via a multiple step ion beam etching process utilizing multiple etching steps. The ion beam is stationary, unidirectional or non-rotational in relation to the surface being etched during the etching steps, but sequential etching steps can utilize an opposite etching direction. Masking elements are used to create additional masking elements, resulting in decreased spacing between adjacent structures and increased structure density.

Abstract: In a rotating disk reactor for growing epitaxial layers on substrate or other CVD reactor system, gas directed toward the substrates at gas inlets at different radial distances from the axis of rotation of the disk has both substantially the same gas flow rate/velocity and substantially the same gas density at each inlet. The gas directed toward portions of the disk remote from the axis may include a higher concentration of a reactant gas than the gas directed toward portions of the disk close to the axis, so that portions of the substrate surfaces at different distances from the axis receive substantially the same amount of reactant gas per unit area, and a combination of carrier gases with different relative molecular weights at different radial distances from the axis of rotation are employed to substantially make equal the gas density in each region of the reactor.