Abstract: An apparatus for measuring contaminants on a surface of a component is provided. An extraction vessel for holding a measurement fluid has an opening adapted to form a meniscus using the measurement fluid. An actuator moves at least one of the extraction vessel and the component to a position where the meniscus is in contact with the surface of the component. A transducer is positioned to provide acoustic energy to the measurement fluid.

Abstract: A method for conditioning ceramic coating on a part for use in a plasma processing chamber is provided. The ceramic coating is wetted with a solution, wherein the solution is formed by mixing a solvent with an electrolyte, wherein from 1% to 10% of the electrolyte dissociates in the solution. The ceramic coating is blasted with particles. The ceramic coating is rinsed.

Abstract: An apparatus for measuring contamination on a critical surface of a part is provided. A vessel for mounting the part is provided. An inert gas source is in fluid connection with the vessel and adapted to provide an inert gas to the vessel. At least one diffuser receives the inert gas from the vessel, wherein the critical surface of the part is exposed to the inert gas when the part is mounted in the vessel. At least one analyzer is adapted to receive inert gas from the at least one diffuser and measures contaminants in the inert gas.

Abstract: A method for conditioning ceramic coating on a part for use in a plasma processing chamber is provided. The ceramic coating is wetted with a solution, wherein the solution is formed by mixing a solvent with an electrolyte, wherein from 1% to 10% of the electrolyte dissociates in the solution. The ceramic coating is blasted with particles. The ceramic coating is rinsed.

Abstract: A method for conditioning a component of a wafer processing chamber is provided. The component is placed in an ultrasonic conditioning solution in an ultrasonic solution tank. Ultrasonic energy is applied through the ultrasonic conditioning solution to the component to clean the component. The component is submerged in a megasonic conditioning solution in a tank. Megasonic energy is applied through the megasonic conditioning solution to the component to clean the component.

Abstract: An apparatus for conditioning a component of a processing chamber is provided. A tank for holding a megasonic conditioning solution is provided. A mount holds the component immersed in a megasonic conditioning solution, when the tank is filled with the megasonic conditioning solution. A megasonic conditioning solution inlet system delivers the megasonic conditioning solution to the tank. A megasonic transducer head comprises at least one megasonic transducer to provide megasonic energy to the megasonic conditioning solution, wherein the megasonic energy is delivered to the component via the megasonic conditioning solution. A megasonic conditioning solution drain system drains the megasonic conditioning solution from the tank at a location above where the component is held in the megasonic conditioning solution. An actuator moves the megasonic transducer head across the tank.

Abstract: An apparatus for conditioning a component of a processing chamber is provided. A tank for holding a megasonic conditioning solution is provided. A mount holds the component immersed in a megasonic conditioning solution, when the tank is filled with the megasonic conditioning solution. A megasonic conditioning solution inlet system delivers the megasonic conditioning solution to the tank. A megasonic transducer head comprises at least one megasonic transducer to provide megasonic energy to the megasonic conditioning solution, wherein the megasonic energy is delivered to the component via the megasonic conditioning solution. A megasonic conditioning solution drain system drains the megasonic conditioning solution from the tank at a location above where the component is held in the megasonic conditioning solution. An actuator moves the megasonic transducer head across the tank.

Abstract: In one embodiment, a dual phase cleaning chamber may include a turbulent mixing chamber, a fluid diffuser, an isostatic pressure chamber and a rupture mitigating nozzle. The turbulent mixing chamber may be in fluid communication with a first fluid inlet and a second fluid inlet. The fluid diffuser may be in fluid communication with the turbulent mixing chamber. The rupture mitigating nozzle may include a first fluid collecting offset, a second fluid collecting offset, and a displacement damping projection. The displacement damping projection may be disposed between the first and second fluid collecting offset and may be offset away from each of the first fluid collecting offset and the second fluid collecting offset, and towards the fluid diffuser. A pressurized cleaning fluid introduced from the first fluid inlet, the second fluid inlet, or both flows through the outlet passage of the first and second fluid collecting offset.

Abstract: In one embodiment, a method for cleaning a showerhead electrode my include sealing a showerhead electrode within a cleaning assembly such that a first cleaning volume is formed on a first side of the showerhead electrode and a second cleaning volume is formed on a second side of the showerhead electrode. An acidic solution can be loaded into the first cleaning volume on the first side of the showerhead electrode. The first cleaning volume on the first side of the showerhead electrode can be pressurized such that at least a portion of the acidic solution flows through one or more of the plurality of gas passages of the showerhead electrode. An amount of purified water can be propelled through the second cleaning volume on the second side of the showerhead electrode, and into contact with the second side of the showerhead electrode.

Abstract: In one embodiment, a dual phase cleaning chamber may include a turbulent mixing chamber, a fluid diffuser, an isostatic pressure chamber and a rupture mitigating nozzle. The turbulent mixing chamber may be in fluid communication with a first fluid inlet and a second fluid inlet. The fluid diffuser may be in fluid communication with the turbulent mixing chamber. The rupture mitigating nozzle may include a first fluid collecting offset, a second fluid collecting offset, and a displacement damping projection. The displacement damping projection may be disposed between the first and second fluid collecting offset and may be offset away from each of the first fluid collecting offset and the second fluid collecting offset, and towards the fluid diffuser. A pressurized cleaning fluid introduced from the first fluid inlet, the second fluid inlet, or both flows through the outlet passage of the first and second fluid collecting offset.

Abstract: In one embodiment, a cleaning assembly may include a modular electrode sealing housing, an acid injection inlet, and a fluid injection inlet. The modular electrode sealing housing may include a high pressure closure member that contains a first cleaning volume and a low pressure closure member that contains a second cleaning volume. The acid injection inlet can be in fluid communication with the first cleaning volume of the high pressure closure member. The fluid injection inlet can be in fluid communication with the second cleaning volume of the low pressure closure member. During normal operation, a showerhead electrode can be sealed within the modular electrode sealing housing such that the first cleaning volume is located on a first side and the second cleaning volume is located on a second side of the showerhead electrode.

Abstract: In one embodiment, a dual phase cleaning chamber may include a turbulent mixing chamber, a fluid diffuser, an isostatic pressure chamber and a rupture mitigating nozzle. The turbulent mixing chamber may be in fluid communication with a first fluid inlet and a second fluid inlet. The fluid diffuser may be in fluid communication with the turbulent mixing chamber. The rupture mitigating nozzle may include a first fluid collecting offset, a second fluid collecting offset, and a displacement damping projection. The displacement damping projection may be disposed between the first and second fluid collecting offset and may be offset away from each of the first fluid collecting offset and the second fluid collecting offset, and towards the fluid diffuser. A pressurized cleaning fluid introduced from the first fluid inlet, the second fluid inlet, or both flows through the outlet passage of the first and second fluid collecting offset.

Abstract: An injector cleaning apparatus with a concentric dual flow introducer and a flow-dispersing injector seat along with a method of cleaning an injector. The concentric dual flow introducer has concentric cleaning fluid flowpaths configured to communicate with a central passage and a plurality of peripheral passages of a gas injector. The input-side injector engaging interface of the concentric dual flow introducer and the flow-dispersing injector seat each have a compressible sealing portion having compressibility sufficient to yield under fluid cleaning surges attributable to initiation and termination of cleaning fluid flow through the injector cleaning apparatus along with resiliency sufficient to prevent abutment of the gas injector and a rigid facing portion of the input-side injector engaging interface and output-side injector engaging interface respectively.

Abstract: In accordance with one embodiment of the present disclosure, an electrode carrier assembly is provided including an electrode carrying annulus and a plurality of electrode mounting members. The electrode carrying annulus includes an electrode containment sidewall that forms an inner or outer radius of the electrode carrying annulus. The electrode carrying annulus further includes a plurality of radial sidewall projections that project radially away from the electrode containment sidewall. The radial sidewall projections each include an upward-facing tapered spacer including an upward-facing micro-mesa. The electrode mounting members each include a downward-facing tapered spacer including a downward-facing micro-mesa. The electrode mounting members are rotatably engaged with the electrode carrying annulus, and are configured to rotate between a free position and a bracketed position.

Abstract: In one embodiment, an electrode polishing assembly may include an electrode securing platen, a plurality of electrode locating fasteners, and an electrode. Each of the electrode locating fasteners may include an electrode spacing shoulder, a variance cancelling shoulder extending from the electrode spacing shoulder, a threaded platen clamping portion extending from the variance cancelling shoulder, and a threaded nut that engages the threaded platen clamping portion. The electrode locating fasteners clamp the electrode securing platen between the threaded nut and the electrode spacing shoulder. The variance cancelling shoulder is at least partially within one of a plurality of variance cancelling passages of the electrode securing platen. A minimum position stack-up is equal to a minimum passage size minus a maximum shoulder size. A maximum position stack-up is equal to a maximum passage size minus a minimum shoulder size. The maximum position stack-up is greater than the minimum position stack-up.

Abstract: In one embodiment, a method for cleaning a showerhead electrode my include sealing a showerhead electrode within a cleaning assembly such that a first cleaning volume is formed on a first side of the showerhead electrode and a second cleaning volume is formed on a second side of the showerhead electrode. An acidic solution can be loaded into the first cleaning volume on the first side of the showerhead electrode. The first cleaning volume on the first side of the showerhead electrode can be pressurized such that at least a portion of the acidic solution flows through one or more of the plurality of gas passages of the showerhead electrode. An amount of purified water can be propelled through the second cleaning volume on the second side of the showerhead electrode, and into contact with the second side of the showerhead electrode.

Abstract: In one embodiment, a cleaning assembly may include a modular electrode sealing housing, an acid injection inlet, and a fluid injection inlet. The modular electrode sealing housing may include a high pressure closure member that contains a first cleaning volume and a low pressure closure member that contains a second cleaning volume. The acid injection inlet can be in fluid communication with the first cleaning volume of the high pressure closure member. The fluid injection inlet can be in fluid communication with the second cleaning volume of the low pressure closure member. During normal operation, a showerhead electrode can be sealed within the modular electrode sealing housing such that the first cleaning volume is located on a first side and the second cleaning volume is located on a second side of the showerhead electrode.

Abstract: In one embodiment, a dual phase cleaning chamber may include a turbulent mixing chamber, a fluid diffuser, an isostatic pressure chamber and a rupture mitigating nozzle. The turbulent mixing chamber may be in fluid communication with a first fluid inlet and a second fluid inlet. The fluid diffuser may be in fluid communication with the turbulent mixing chamber. The rupture mitigating nozzle may include a first fluid collecting offset, a second fluid collecting offset, and a displacement damping projection. The displacement damping projection may be disposed between the first and second fluid collecting offset and may be offset away from each of the first fluid collecting offset and the second fluid collecting offset, and towards the fluid diffuser. A pressurized cleaning fluid introduced from the first fluid inlet, the second fluid inlet, or both flows through the outlet passage of the first and second fluid collecting offset.

Abstract: In one embodiment, an electrode polishing assembly may include an electrode securing platen, a plurality of electrode locating fasteners, and an electrode. Each of the electrode locating fasteners may include an electrode spacing shoulder, a variance cancelling shoulder extending from the electrode spacing shoulder, a threaded platen clamping portion extending from the variance cancelling shoulder, and a threaded nut that engages the threaded platen clamping portion. The electrode locating fasteners clamp the electrode securing platen between the threaded nut and the electrode spacing shoulder. The variance cancelling shoulder is at least partially within one of a plurality of variance cancelling passages of the electrode securing platen. A minimum position stack-up is equal to a minimum passage size minus a maximum shoulder size. A maximum position stack-up is equal to a maximum passage size minus a minimum shoulder size. The maximum position stack-up is greater than the minimum position stack-up.

Abstract: In accordance with one embodiment of the present disclosure, an electrode carrier assembly is provided including an electrode carrying annulus and a plurality of electrode mounting members. The electrode carrying annulus includes an electrode containment sidewall that forms an inner or outer radius of the electrode carrying annulus. The electrode carrying annulus further includes a plurality of radial sidewall projections that project radially away from the electrode containment sidewall. The radial sidewall projections each include an upward-facing tapered spacer including an upward-facing micro-mesa. The electrode mounting members each include a downward-facing tapered spacer including a downward-facing micro-mesa. The electrode mounting members are rotatably engaged with the electrode carrying annulus, and are configured to rotate between a free position and a bracketed position.