Abstract: A composition mixture control system for an equipment front end module includes a manifold, flow controllers and a composition controller. The flow controllers are configured to control flow of respective gases to the manifold, where the manifold is configured to mix the gases received from the flow controllers and direct a resultant gas mixture to an enclosure in the equipment front end module. The composition controller is configured to control operation of the flow controllers to adjust a composition in the enclosure to a set target composition including the gases.

Abstract: A method for cleaning a load lock in a substrate processing system includes, in a first period, opening a first valve in fluid communication with a gas source to supply gas through a first vent into a gas volume of the load lock. The gas is supplied at a pressure and flow rate sufficient to disturb particles from surfaces of the load lock. The method includes, in a second period subsequent to the first period and with the first valve opened, opening a second valve in fluid communication with a pump and turning on the pump to flush the gas and particles from the gas volume of the load lock, and, in a third period subsequent to the second period, closing the first valve while continuing to pump the gas and the particles from the gas volume of the load lock via the second valve.

Abstract: A method for cleaning a load lock in a substrate processing system includes, in a first period, opening a first valve in fluid communication with a gas source to supply gas through a first vent into a gas volume of the load lock. The gas is supplied at a pressure and flow rate sufficient to disturb particles from surfaces of the load lock. The method includes, in a second period subsequent to the first period and with the first valve opened, opening a second valve in fluid communication with a pump and turning on the pump to flush the gas and particles from the gas volume of the load lock, and, in a third period subsequent to the second period, closing the first valve while continuing to pump the gas and the particles from the gas volume of the load lock via the second valve.

Abstract: A chamber is formed to enclose a processing region. A passageway is configured to provide for entry of a substrate into the processing region and removal of the substrate from the processing region. A substrate support structure is disposed within the processing region and configured to support the substrate within the processing region. At least one gas input is configured to supply one or more gases to the processing region. At least one gas output is configured to exhaust gases from the processing region. A humidity control device is configured to control a relative humidity within the processing region. At least one heating device is disposed to provide temperature control of the substrate within the processing region. The processing region of the chamber is directly accessible from a substrate handling module configured to operate at atmospheric pressure.

Abstract: A chamber is formed to enclose a processing region. A passageway is configured to provide for entry of a substrate into the processing region and removal of the substrate from the processing region. A substrate support structure is disposed within the processing region and configured to support the substrate within the processing region. At least one gas input is configured to supply one or more gases to the processing region. At least one gas output is configured to exhaust gases from the processing region. A humidity control device is configured to control a relative humidity within the processing region. At least one heating device is disposed to provide temperature control of the substrate within the processing region. The processing region of the chamber is directly accessible from a substrate handling module configured to operate at atmospheric pressure.

Abstract: A method for cleaning a chamber of a substrate processing system includes maintaining the chamber at a first predetermined pressure and, without a substrate present within the chamber, providing, from a fluid source via a nozzle assembly, a fluid, and injecting the fluid into the chamber via the nozzle assembly. The fluid source is maintained at a second predetermined pressure that is greater than the first predetermined pressure. Injecting the fluid into the chamber maintained at the first predetermined pressure causes the fluid to aerosolize into a mixture of gas and solid particles.

Abstract: A substrate processing system includes a chamber configured to process a semiconductor substrate. At least one surface of the chamber includes a high surface area finish. A purge/vent system is configured to selectively supply purge gas over the high surface area finish of the at least one surface to trap particles in the high surface area finish without opening the chamber. The high surface area finish on the at least one surface of the chamber has a porosity within a predetermined range from 30-60%. The porosity is defined by a normalized density of the high surface area finish relative to an underlying native bulk material of the at least one surface of the chamber.

Abstract: A method for diagnosing a particle removal system of a substrate processing system includes dispersing synthetic particles onto a substrate; exciting the synthetic particles using a light source having a first predetermined wavelength; measuring photoluminescence of the synthetic particles at a second predetermined wavelength that is different than the first predetermined wavelength and determining a first number of the synthetic particles on the substrate; at least one of moving the substrate through a chamber or processing the substrate in the chamber of the substrate processing system; exciting the synthetic particles using light having the first predetermined wavelength; measuring photoluminescence of the synthetic particles at the second predetermined wavelength that is different than the first predetermined wavelength; and determining a second number of the synthetic particles on the substrate based on the measuring.

Abstract: A plasma confinement ring assembly with a single movable lower ring can be used for controlling wafer area pressure in a capacitively coupled plasma reaction chamber wherein a wafer is supported on a lower electrode assembly and process gas is introduced into the chamber by an upper showerhead electrode assembly. The assembly includes an upper ring, the lower ring, hangers, hanger caps, spacer sleeves and washers. The lower ring is supported by the hangers and is movable towards the upper ring when the washers come into contact with the lower electrode assembly during adjustment of the gap between the upper and lower electrodes. The hanger caps engage upper ends of the hangers and fit in upper portions of hanger bores in the upper ring. The spacer sleeves surround lower sections of the hangers and fit within lower portions of the hanger bores. The washers fit between enlarged heads of the hangers and a lower surface of the lower ring.

Abstract: An edge ring assembly used in a plasma etching chamber includes a dielectric coupling ring and a conductive edge ring. In one embodiment, the dielectric coupling ring has an annular projection extending axially upward from its inner periphery. The dielectric coupling ring is adapted to surround a substrate support in a plasma etching chamber. The conductive edge ring is adapted to surround the annular projection of the dielectric coupling ring. A substrate supported on the substrate support overhangs the substrate support and overlies the annular projection of the dielectric coupling ring and a portion of the conductive edge ring. In another embodiment, the dielectric coupling ring has a rectangular cross section. The dielectric coupling ring and the conductive edge ring are adapted to surround a substrate support in a plasma etching chamber. A substrate supported on the substrate support overhangs the substrate support and overlies a portion of the conductive edge ring.

Abstract: An edge ring assembly used in a plasma etching chamber includes a dielectric coupling ring and a conductive edge ring. In one embodiment, the dielectric coupling ring has an annular projection extending axially upward from its inner periphery. The dielectric coupling ring is adapted to surround a substrate support in a plasma etching chamber. The conductive edge ring is adapted to surround the annular projection of the dielectric coupling ring. A substrate supported on the substrate support overhangs the substrate support and overlies the annular projection of the dielectric coupling ring and a portion of the conductive edge ring. In another embodiment, the dielectric coupling ring has a rectangular cross section. The dielectric coupling ring and the conductive edge ring are adapted to surround a substrate support in a plasma etching chamber. A substrate supported on the substrate support overhangs the substrate support and overlies a portion of the conductive edge ring.

Abstract: A method of increasing mean time between cleans of a plasma etch chamber and chamber parts lifetimes is provided. Semiconductor substrates are plasma etched in the chamber while using at least one sintered silicon nitride component exposed to ion bombardment and/or ionized halogen gas. The sintered silicon nitride component includes high purity silicon nitride and a sintering aid consisting of silicon dioxide. A plasma processing chamber is provided including the sintered silicon nitride component. A method of reducing metallic contamination on the surface of a silicon substrate during plasma processing is provided with a plasma processing apparatus including one or more sintered silicon nitride components. A method of manufacturing a component exposed to ion bombardment and/or plasma erosion in a plasma etch chamber, comprising shaping a powder composition consisting of high purity silicon nitride and silicon dioxide and densifying the shaped component.

Abstract: A plasma confinement ring assembly with a single movable lower ring can be used for controlling wafer area pressure in a capacitively coupled plasma reaction chamber wherein a wafer is supported on a lower electrode assembly and process gas is introduced into the chamber by an upper showerhead electrode assembly. The assembly includes an upper ring, the lower ring, hangers, hanger caps, spacer sleeves and washers. The lower ring is supported by the hangers and is movable towards the upper ring when the washers come into contact with the lower electrode assembly during adjustment of the gap between the upper and lower electrodes. The hanger caps engage upper ends of the hangers and fit in upper portions of hanger bores in the upper ring. The spacer sleeves surround lower sections of the hangers and fit within lower portions of the hanger bores. The washers fit between enlarged heads of the hangers and a lower surface of the lower ring.

Abstract: An edge ring assembly used in a plasma etching chamber includes a dielectric coupling ring and a conductive edge ring. In one embodiment, the dielectric coupling ring has an annular projection extending axially upward from its inner periphery. The dielectric coupling ring is adapted to surround a substrate support in a plasma etching chamber. The conductive edge ring is adapted to surround the annular projection of the dielectric coupling ring. A substrate supported on the substrate support overhangs the substrate support and overlies the annular projection of the dielectric coupling ring and a portion of the conductive edge ring. In another embodiment, the dielectric coupling ring has a rectangular cross section. The dielectric coupling ring and the conductive edge ring are adapted to surround a substrate support in a plasma etching chamber. A substrate supported on the substrate support overhangs the substrate support and overlies a portion of the conductive edge ring.

Abstract: A method of increasing mean time between cleans of a plasma etch chamber and chamber parts lifetimes is provided. Semiconductor substrates are plasma etched in the chamber while using at least one sintered silicon nitride component exposed to ion bombardment and/or ionized halogen gas. The sintered silicon nitride component includes high purity silicon nitride and a sintering aid consisting of silicon dioxide. A plasma processing chamber is provided including the sintered silicon nitride component. A method of reducing metallic contamination on the surface of a silicon substrate during plasma processing is provided with a plasma processing apparatus including one or more sintered silicon nitride components. A method of manufacturing a component exposed to ion bombardment and/or plasma erosion in a plasma etch chamber, comprising shaping a powder composition consisting of high purity silicon nitride and silicon dioxide and densifying the shaped component.

Abstract: A system and method for in situ measurement and maintenance of preferred pad smoothness in a CMP process is disclosed. The system includes a linear polisher having one or more sensors for detecting fluid pressure, fluid flow or motor current at the linear polisher during a polishing process. A controller receiving the information provided by the sensors includes an algorithm for adjusting the pad conditioning process to achieve a desired pad smoothness based on the sensor data. The method includes obtaining baseline data on preferred linear polisher characteristics associated with desired pad smoothness and using the baseline data to adjust a pad conditioning regimen on a linear polisher to achieve the desired pad smoothness in situ.

Abstract: A method and assembly for generating a hydrodynamic air bearing is described, wherein at least one rotor is rotated to force air through channels defined in a platen located adjacent to a linear belt and the forced air is directed to the linear belt. The method includes rotating at least one rotor with a motor such that the rotor forces air through channels defined in a platen, and the air is directed toward a linear belt. The assembly includes a housing in which a platen, rotors, and a bearing plate are located.

Abstract: A conditioning apparatus for use in a CMP system is provided along with an associated method of operation. The conditioning apparatus includes rotation mechanics and oscillation mechanics. The rotation mechanics are capable of rotating a shaft which causes a holder and a conditioning substrate to be rotated. The oscillation mechanics are capable of moving a position of the shaft within a region defined by a peripheral boundary that is less than and within an outer periphery of the conditioning substrate. A conditioning substrate backing is also included in the conditioning apparatus. The conditioning substrate backing defines a differential pressure distribution that is capable of being applied to the conditioning substrate.

Abstract: An apparatus for improving performance of a wafer polishing apparatus is described. The apparatus includes a platen in a support assembly having a plurality of fluid channels and at least one region of altered topography positioned on a portion of the platen surface.

Abstract: A belt wiper that can be used in a linear belt-type chemical mechanical planarization (CMP) system to maintain a belt pad is provided. The belt wiper mitigates disturbances within a detection region important to a belt pad steering system. Also, the belt wiper mitigates the obscuring of optical components important to operation of an endpoint detection system. Thus, the belt wiper, by wiping the underside of the belt pad will preserve the functionality of both the belt pad steering system and the endpoint detection system.