The present disclosure describes an apparatus. The apparatus includes a chuck for placing an object thereon, a gas passage extending along a periphery of an outer sidewall of the chuck and separating the chuck into an inner portion and a sidewall portion, and a plurality of gas holes through the sidewall portion and configured to connect a gas external to the chuck to the gas passage.

A confinement ring for a substrate processing system includes a lower wall, an outer wall, and an upper wall defining a plasma region within the confinement ring. A first plurality of slots is formed within the lower wall. The first plurality of slots provides fluid communication between the plasma region within the confinement ring and an environment external to the confinement ring. A recess is defined in a lower surface of the lower wall. A lower ring is arranged within the recess of the lower surface. The lower ring includes a second plurality of slots that provides fluid communication between the plasma region within the confinement ring and an environment external to the confinement ring via the first plurality of slots.

Provided are a faraday cleaning device and a plasma processing system, the device comprising a reaction chamber, a bias electrode, a wafer, a chamber cover, a coupling window, an air inlet nozzle, a vertical coil, and a faraday layer, wherein the coupling window is installed at the upper end face of the chamber cover, the chamber cover is installed at the upper end face of the reaction chamber, the bias electrode is assembled inside the reaction chamber, the wafer is installed at the upper end face of the bias electrode, the air inlet nozzle is assembled inside the coupling window, the faraday layer is installed at the upper end face of the coupling window, and the vertical coil is assembled at the upper end face of the faraday layer.

Embodiments described herein generally related to a substrate processing apparatus, and more specifically to an improved showerhead assembly for a substrate processing apparatus. The showerhead assembly includes a chill plate, a gas plate, and a gas distribution plate having a top surface and a bottom surface. A plurality of protruded features contacts the top surface of the gas distribution plate. A fastener and an energy storage structure is provided on the protruded features. The energy storage structure is compressed by the fastener and axially loads at least one of the protruded features to compress the chill plate, the gas plate and the gas distribution plate.

Embodiments described herein are applicable for use in all types of plasma assisted or plasma enhanced processing chambers and also for methods of plasma assisted or plasma enhanced processing of a substrate. More specifically, embodiments of this disclosure include a broadband filter assembly, also referred to herein as a filter assembly, that is configured to reduce and/or prevent RF leakage currents from being transferred from one or more RF driven components to a ground through other electrical components that are directly or indirectly electrically coupled to the RF driven components and ground with high input impedance (low current loss) making it compatible with shaped DC pulse bias applications.

A tunable edge sheath (TES) system includes a coupling ring configured to couple to a bottom surface of an edge ring that surrounds a wafer support area within a plasma processing chamber. The TES system includes an annular-shaped electrode embedded within the coupling ring. The TES system includes a plurality of radiofrequency signal supply pins coupled to the electrode within the coupling ring. Each of the plurality of radiofrequency signal supply pins extends through a corresponding hole formed through a bottom surface of the coupling ring. The TES system includes a plurality of radiofrequency signal filters respectively connected to the plurality of radiofrequency supply pins. Each of the plurality of radiofrequency signal filters is configured to provide a high impedance to radiofrequency signals used to generate a plasma within the plasma processing chamber.

A plasma treatment chamber comprises one or more sidewalls and a support surface within the sidewalls holds a workpiece. An array of individual gas injectors is distributed about the sidewalls. Pump ports are along the sidewalls to eject gas from the chamber. Aa etch rate uniformity of a material on the workpiece is controlled by: using the array gas injectors to inject one or more gas flows in across the workpiece; injecting a first gas flow from a first set of adjacent individual gas injectors to etch the materials on the workpiece; and simultaneously injecting a second gas flow from remaining gas injectors. The second gas flow either dilutes the first gas flow to reduce an area on the workpiece having a faster etch rate, or acts as an additional etchant to increase the etch rate in the area of the workpiece having the faster etch rate.

A substrate processing method includes: providing a substrate including a silicon-containing film in a chamber; supplying a processing gas including HF gas into the chamber; etching the silicon-containing film with plasma generated from the processing gas, thereby forming a recess in the silicon-containing film; and controlling a partial pressure of the HF gas to decrease the partial pressure of the HF gas with an increase of an aspect ratio of the recess.

Methods and apparatus for preparing a protective coating are described. In one example aspect, an apparatus for preparing a protective coating includes a chamber, a substrate positioned within the chamber configured to hold at least a target object, an inlet pipe configured to direct a monomer vapor into the chamber, and one or more electrodes configured to perform a chemical vapor deposition process to produce a multi-layer coating. The chemical vapor deposition process comprises multiple cycles, each cycle comprising a pretreatment phase and a coating phase to produce a layer of the multi-layer coating.

Embodiments of the present disclosure relate to a system for pulsed direct-current (DC) biasing and clamping a substrate. In one embodiment, the system includes a plasma chamber having an electrostatic chuck (ESC) for supporting a substrate. An electrode is embedded in the ESC and is electrically coupled to a biasing and clamping network. The biasing and clamping network includes at least a shaped DC pulse voltage source and a clamping network. The clamping network includes a DC source and a diode, and a resistor. The shaped DC pulse voltage source and the clamping network are connected in parallel. The biasing and clamping network automatically maintains a substantially constant clamping voltage, which is a voltage drop across the electrode and the substrate when the substrate is biased with pulsed DC voltage, leading to improved clamping of the substrate.