Chucks for supporting semiconductor wafers during certain processing operations are disclosed. The chucks may include a recessed region near the outer perimeter of the wafer that has one or more surfaces that face towards the wafer but are recessed therefrom so as to not contact the wafer around the perimeter of the wafer. The use of such a recessed region prevents direct thermally conductive contact between the chuck and the wafer, thereby allowing the wafer to achieve a more uniform temperature distribution in certain process conditions. This has the further effect of causing certain processing operations to be more uniform with respect to edge-center deposition (or etch) layer thickness.

Exemplary substrate support assemblies may include a chuck body defining a substrate support surface. The substrate support surface may define a plurality of protrusions that extend upward from the substrate support surface. The substrate support surface may define an annular groove and/or ridge. A subset of the plurality of protrusions may be disposed within the annular groove and/or ridge. The substrate support assemblies may include a support stem coupled with the chuck body.

A multi-deposition chamber apparatus is provided that includes a first deposition chamber that includes a substrate holder, a retractable sputter gun, a gate valve, an output port, a retractable chamber separator, a gas input port, a gas output port, and an electron cyclotron resonance plasma source, where the retractable chamber separator is configured to selectively segment the first deposition chamber to form a second deposition chamber, where the second deposition chamber comprises the substrate holder, the gas input port, the gas output port and the electron cyclotron resonance plasma source.

A multi-deposition chamber apparatus is provided that includes a first deposition chamber that includes a substrate holder, a retractable sputter gun, a gate valve, an output port, a retractable chamber separator, a gas input port, a gas output port, and an electron cyclotron resonance plasma source, where the retractable chamber separator is configured to selectively segment the first deposition chamber to form a second deposition chamber, where the second deposition chamber comprises the substrate holder, the gas input port, the gas output port and the electron cyclotron resonance plasma source.

Embodiments of the invention generally relate to a process kit for a semiconductor processing chamber, and a semiconductor processing chamber having a kit. More specifically, embodiments described herein relate to a process kit including a deposition ring and a pedestal assembly. The components of the process kit work alone, and in combination, to significantly reduce their effects on the electric fields around a substrate during processing.

An installation having a housing, a substrate support (20) received in the housing, diffuser (42) for diffusing an inert gas towards the substrate support, and at least one head (30) defining an inner volume (V) opened opposite to the top, the head being provided with at least two electrodes (8, 8′, 8″) for creating an electric discharge and with an injector (7, 7′, 7″) for injecting a gaseous mixture towards the substrate. The injector has at least one injection tube (7, 7′, 7″) placed between two adjacent electrodes or between one electrode and a peripheral wall, the tube being provided with injection holes facing the substrate support, for injecting the gaseous mixture on the substrate, whereas diffuser is provided inside the head, the injection tube being placed between the substrate support and the diffuser so that, in use, the gaseous mixture is urged against the substrate by the inert gas.

An installation having a housing, a substrate support (20) received in the housing, diffuser (42) for diffusing an inert gas towards the substrate support, and at least one head (30) defining an inner volume (V) opened opposite to the top, the head being provided with at least two electrodes (8, 8′, 8″) for creating an electric discharge and with an injector (7, 7′, 7″) for injecting a gaseous mixture towards the substrate. The injector has at least one injection tube (7, 7′, 7″) placed between two adjacent electrodes or between one electrode and a peripheral wall, the tube being provided with injection holes facing the substrate support, for injecting the gaseous mixture on the substrate, whereas diffuser is provided inside the head, the injection tube being placed between the substrate support and the diffuser so that, in use, the gaseous mixture is urged against the substrate by the inert gas.

A method of depositing a silicon film on a recess formed in a surface of a substrate is provided. The substrate is placed on a rotary table in a vacuum vessel, so as to pass through first, second, and third processing regions in the vacuum vessel. An interior of the vacuum vessel is set to a first temperature capable of breaking an Si—H bond. In the first processing region, Si.sub.2H.sub.6 gas having a temperature less than the first temperature is supplied to form an SiH.sub.3 molecular layer on its surface. In the second processing region, a silicon atomic layer is exposed on the surface of the substrate, by breaking the Si—H bond in the SiH.sub.3 molecular layer. In the third processing region, by anisotropic etching, the silicon atomic layer on an upper portion of an inner wall of the recess is selectively removed.

There is provided a plasma generating device that includes a first electrode connected to a high-frequency power supply, and a second electrode to be grounded, a buffer structure configured to form a buffer chamber that accommodates the first and second electrodes wherein the first electrode and the second electrode are alternately arranged such that a number of electrodes of the first electrode and the second electrode are in an odd number of three or more in total, and wherein the second electrode is used in common for two of the first electrode being respectively adjacent to the second electrode used in common, and wherein a gas supply port that supplies gas into a process chamber is installed on a wall surface of the buffer structure.

The present inventive concept is a substrate processing method in which processing steps are carried out on a substrate supported on a support unit in a processing space that is divided into a first processing area and a second processing area, the substrate processing method comprising: a step in which a first gas and a first purge gas are sprayed in the first processing area; and a step in which a second purge gas and a second gas are sequentially sprayed in the second processing area.