A plasma processing apparatus includes a processing vessel; a placing table, serving as a lower electrode, disposed within the processing vessel; an upper electrode serving as a facing electrode of the placing table; a plasma processor configured to form a gas within the processing vessel into plasma by supplying a high frequency power and to process a processing target object on the placing table with the plasma; a cover member configured to cover the upper electrode from thereabove; a cooler provided within the cover member and configured to cool the upper electrode with a coolant having a temperature lower than a dew point temperature of exterior air outside the processing vessel; and a gas supply configured to supply a low-dew point gas having a dew point temperature lower than the dew point temperature of the exterior air into a space surrounded by the cover member and the upper electrode.

A plasma processing method performed using a plasma processing apparatus includes a first step of forming a first film on a pattern formed on a substrate and having dense and coarse areas, and a second step of performing sputtering or etching on the first film.

A method MT includes etching a wafer W using plasma generated in a processing container. The etching includes a process of inclining and rotating a holding structure holding the wafer W during execution of the etching and the process successively creating a plurality of inclined rotation states RT(, t) with respect to the holding structure. In the inclined rotation states, the wafer W is rotated about a central axis of the wafer W over a predetermined process time while maintaining a state where the central axis is inclined with respect to a reference axis of the processing container which is in the same plane as the central axis. A combination of a value of an inclination angle AN of the central axis with respect to the reference axis and the process time t differs for each of the plurality of inclined rotation states.

A substrate processing system includes model generation and setpoint modules. The model generation module receives a first time trace based on an output of an endpoint sensor and obtains a target setpoint. A portion of the first time trace is indicative of an endpoint at which a feature has been created in a first substrate. The target setpoint is generated based on a metrology process and is used to compensate for erosion of a first edge ring. The model generation module generates a conversion model based on the portion and the target setpoint. The setpoint module: based on the output, receives a second time trace that is generated subsequent to generation of the first time trace; and based on the conversion model, converts the second time trace to a predicted erosion compensation setpoint, which is set while processing a second substrate using the first or a second edge ring.

A substrate processing apparatus includes: a processing chamber including a plasma generating region, a gas mixing region, and a substrate processing region; a first gas supply line supplying a first processing gas to the plasma generating region; a second gas supply line supplying a second processing gas to the gas mixing region; an ion blocker disposed between the plasma generating region and the gas mixing region; and a shower head disposed between the gas mixing region and the substrate processing region, wherein the ion blocker has a first blocker flow path unit connected to the second gas supply line and open to the plasma generating region, so that the second processing gas is supplied to the plasma generating region.

Provided is a method for manufacturing a wide-gap semiconductor substrate enabling formation of a device having low power loss while maintaining high mechanical strength. This method is an etching method for etching a wide-gap semiconductor substrate (W) placed on a platen (15) disposed in a processing chamber (11) by means of plasma generated from an etching gas so that only a device formation region of the wide-gap semiconductor substrate (W) is thinned, the method including a step of supplying the etching gas into the processing chamber (11) and generating the plasma from the etching gas, and a step of applying a bias potential to the platen (15) to etch only the device formation region of the wide-gap semiconductor substrate (W) so as to thin only the device formation region.

Disclosed is an apparatus for treating a substrate. The apparatus includes a chamber having a space therein in which the substrate is treated, a support unit that supports the substrate in the chamber, a gas supply unit that supplies gas into the chamber, and a plasma generation unit that excites the gas in the chamber into a plasma state. The support unit includes a support plate on which the substrate is placed, a high-frequency power supply that supplies high-frequency power to the support plate, and a high-frequency transmission line through which the high-frequency power is supplied from the high-frequency power supply to the support plate. Characteristic impedance of the high-frequency transmission line is variable.

In a plasma processing apparatus, a mounting table have a first mounting surface on which a target object or a jig is mounted and a second mounting surface on which a ring member is mounted. The jig is used for measuring a thickness of the ring member disposed around the target object and having a facing portion facing an upper surface of the ring member. Elevating mechanisms lift or lower the ring member with respect to the second mounting surface. An acquisition unit acquires gap information indicating a gap dimension between the second mounting surface and the facing portion of the jig. A measurement unit measures a lifted distance of the ring member from the second mounting surface. A thickness calculation unit calculates the thickness of the ring member based on the gap dimension and the measured lifted distance of the ring member.

Process kits, processing chambers, and methods for processing a substrate are provided. The process kit includes an edge ring, an adjustable tuning ring, and an actuating mechanism. The edge ring has a first ring component interfaced with a second ring component that is movable relative to the first ring component forming a gap therebetween. The second ring component has an inner thickness that is less than an outer thickness, and at least a portion of an upper surface of the second ring component is inwardly angled towards the ring first component. The adjustable tuning ring has an upper surface that contacts the lower surface of the second ring component. The actuating mechanism is interfaced with the lower surface of the adjustable tuning ring and is configured to actuate the adjustable tuning ring such that the gap between the first ring component and the second ring component is varied.

A plasma processing device in which plasma processing uniformity is improved up to an outer peripheral portion of a wafer and the number of non-defective devices that can be manufactured from one wafer is increased. The plasma processing device includes a vacuum container; a mounting table, a susceptor ring that covers an outer peripheral portion of an electrode base material, and an insulation ring covered by the susceptor ring and surrounding the electrode base material, and thin film electrode formed on an upper surface and a part of a surface facing the outer periphery of the electrode base material; a first high frequency power applied to the electrode base material a second high frequency power applied to the thin film electrode; a plasma generating unit that generates plasma on an upper portion of the mounting table inside the vacuum container; and a control unit.