Capacitive sensors and capacitive sensing data integration for plasma chamber condition monitoring are described. In an example, a plasma chamber monitoring system includes a plurality of capacitive sensors, a capacitance digital converter, and an applied process server coupled to the capacitance digital converter, the applied process server including a system software. The capacitance digital converter includes an isolation interface coupled to the plurality of capacitive sensors, a power supply coupled to the isolation interface, a field-programmable gate-array firmware coupled to the isolation interface, and an application-specific integrated circuit coupled to the field-programmable gate-array firmware.

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.

A method of cleaning a substrate processing apparatus that etches a film including a metal includes (a) providing an inert gas, and removing a metal-containing deposition by plasma generated from the inert gas; and (b) after (a), providing a gas containing a fluorine-containing gas and an oxygen-containing gas, and removing a silicon-containing deposition by plasma generated from the gas containing the fluorine-containing gas and the oxygen-containing gas.

Examples of a cleaning method includes supplying a cleaning gas into an exhaust duct that provides an exhaust flow passage of a gas supplied to an area above a susceptor, the exhaust duct having a shape surrounding the susceptor in plan view, and activating the cleaning gas to clean an inside of the exhaust duct.

Methods of cleaning a PVD chamber component, for example, process kit components are disclosed. The method comprises at least one of directing a jet of pressurized fluid at a surface of the PVD chamber component, directing pressurized carbon dioxide at the surface of the PVD chamber component, placing the PVD chamber component in a liquid and producing ultrasonic waves in the liquid to further remove contaminants from the surface of the PVD chamber component, using a plasma to clean the surface of the PVD chamber component, subjecting the PVD chamber component to a thermal cycle by heating up to a peak temperature of at least 50 C. and subsequently cooling down to room, placing the PVD chamber component in a process chamber, reducing the pressure in the process chamber below atmospheric pressure and purging the process chamber with a gas, surface conditioning the surface of the PVD chamber component, and drying the surface of the PVD chamber component by directing a gas on the surface of the PVD chamber component.

A cleanliness monitor for monitoring a cleanliness of a vacuum chamber. The cleanliness monitor may include a mass spectrometer, a molecule aggregation and release unit and an analyzer. The molecule aggregation and release unit is configured to (a) aggregate, during an aggregation period, organic molecules that are present in the vacuum chamber and (b) induce, during a release period, a release of a subset of the organic molecules towards the mass spectrometer. The mass spectrometer is configured to monitor an environment within the vacuum chamber and to generate detection signals indicative of a content of the environment; wherein a first subset of the detection signals is indicative of a presence of the subset of the organic molecules. The analyzer is configured to determine the cleanliness of the vacuum chamber based on the detection signals.

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.

A showerhead for a substrate processing chamber includes: inner walls; an inner plenum between the inner walls; and a faceplate having a first surface and a second surface that is opposite the first surface. Holes through the faceplate extend from the first surface to the second surface. A first inlet is fluidly connected to the inner plenum. A first outer plenum is between the inner walls and outer walls. A second outer plenum is between the inner walls and the outer walls. Coolant: fluidly connect the first outer plenum with the second outer plenum; are located within the faceplate between the first and second surfaces; and are fluidly isolated from the holes. The showerhead also includes a second inlet that is fluidly connected to the first outer plenum.

There is provided a method for etching an organic region of a substrate. In the method, an organic film is formed on a surface in a chamber of a plasma processing apparatus. The surface extends out around a region where the substrate is to be disposed in the chamber of the plasma processing apparatus, and the organic region is etched by chemical species from plasma in the chamber.

A substrate processing method capable of preventing a damage to a reactor and a lower film includes: supplying a substrate having a pattern structure; forming a layer on the pattern structure; generating active species by applying plasma on the substrate; and selectively etching a layer on the pattern structure generated by the active species by performing isotropic etching on the layer, wherein the applying of the plasma includes: increasing a density of the active species; and increasing a mobility of the active species.