An exclusion ring for semiconductor wafer processing includes an outer circumferential segment having a first thickness and an inner circumferential segment having a second thickness, with the first thickness being greater than the second thickness. The top surface of an inner circumferential segment and the top surface of the outer circumferential segment define a common top surface for the exclusion ring. A plurality of flow paths is formed within the outer circumferential segment, with each of the flow paths extending radially through the plurality of flow paths provides for exhaust of a wafer edge gas from the pocket where a wafer has an edge thereof disposed below part of the inner circumferential portion. The exhausting of the wafer edge gas from the pocket prevents up-and-down movement of the exclusion ring when bowed wafers are processed.

The present invention provides a growth method of grapheme, which at least comprises the following steps: S1: providing an insulating substrate, placing the insulating substrate in a growth chamber; S2: heating the insulating substrate to a preset temperature, and introducing a gas containing catalytic element into the growth chamber; S3: feeding carbon source into the growth chamber and growing a graphene thin film on the insulating substrate. The present invention adopts a catalytic manner of introducing catalytic element, and rapid grows a high quality graphene on the insulating substrate, which avoids the transition process of the graphene, enables to improve the production yield of the graphene, reduces the growth cost of the graphene, and thus the mass production can be facilitated. The graphene grown by the present invention may be applied in the field of novel graphene electronic devices, graphene transparent conducting film, transparent conducting coating and the like.

The present invention provides a growth method of grapheme, which at least comprises the following steps: S1: providing an insulating substrate, placing the insulating substrate in a growth chamber; S2: heating the insulating substrate to a preset temperature, and introducing a gas containing catalytic element into the growth chamber; S3: feeding carbon source into the growth chamber and growing a graphene thin film on the insulating substrate. The present invention adopts a catalytic manner of introducing catalytic element, and rapid grows a high quality graphene on the insulating substrate, which avoids the transition process of the graphene, enables to improve the production yield of the graphene, reduces the growth cost of the graphene, and thus the mass production can be facilitated. The graphene grown by the present invention may be applied in the field of novel graphene electronic devices, graphene transparent conducting film, transparent conducting coating and the like.

Provided are apparatuses and methods for performing deposition and etch processes in an integrated tool. An apparatus may include a plasma processing chamber that is a capacitively-coupled plasma reactor, and the plasma processing chamber can include a showerhead that includes a top electrode and a pedestal that includes a bottom electrode. The apparatus may be configured with an RF hardware configuration so that an RF generator may power the top electrode in a deposition mode and power the bottom electrode in an etch mode. In some implementations, the apparatus can include one or more switches so that at least an HFRF generator is electrically connected to the showerhead in a deposition mode, and the HFRF generator and an LFRF generator is electrically connected to the pedestal and the showerhead is grounded in the etch mode.

Provided are apparatuses and methods for performing deposition and etch processes in an integrated tool. An apparatus may include a plasma processing chamber that is a capacitively-coupled plasma reactor, and the plasma processing chamber can include a showerhead that includes a top electrode and a pedestal that includes a bottom electrode. The apparatus may be configured with an RF hardware configuration so that an RF generator may power the top electrode in a deposition mode and power the bottom electrode in an etch mode. In some implementations, the apparatus can include one or more switches so that at least an HFRF generator is electrically connected to the showerhead in a deposition mode, and the HFRF generator and an LFRF generator is electrically connected to the pedestal and the showerhead is grounded in the etch mode.

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 plasma-enhanced chemical vapor deposition apparatus for depositing a lithium (Li)-based film on a surface of a substrate includes a reaction chamber, in which the substrate is disposed; a first source supply configured to supply a Li source material into the reaction chamber; a second source supply configured to supply phosphor (P) and oxygen (O) source materials and a nitrogen (N) source material into the reaction chamber; a power supply configured to supply power into the reaction chamber to generate plasma in the reaction chamber; and a controller configured to control the power supply to turn on or off generation of the plasma.

A plasma-enhanced chemical vapor deposition apparatus for depositing a lithium (Li)-based film on a surface of a substrate includes a reaction chamber, in which the substrate is disposed; a first source supply configured to supply a Li source material into the reaction chamber; a second source supply configured to supply phosphor (P) and oxygen (O) source materials and a nitrogen (N) source material into the reaction chamber; a power supply configured to supply power into the reaction chamber to generate plasma in the reaction chamber; and a controller configured to control the power supply to turn on or off generation of the plasma.

Provided are methods and systems for providing silicon-containing films. The composition of the silicon-containing film can be controlled by the choice of the combination of precursors and the ratio of flow rates between the precursors. The silicon-containing films can be deposited on a substrate by flowing two different organo-silicon precursors to mix together in a reaction chamber. The organo-silicon precursors react with one or more radicals in a substantially low energy state to form the silicon-containing film. The one or more radicals can be formed in a remote plasma source.

Provided are methods and systems for providing silicon-containing films. The composition of the silicon-containing film can be controlled by the choice of the combination of precursors and the ratio of flow rates between the precursors. The silicon-containing films can be deposited on a substrate by flowing two different organo-silicon precursors to mix together in a reaction chamber. The organo-silicon precursors react with one or more radicals in a substantially low energy state to form the silicon-containing film. The one or more radicals can be formed in a remote plasma source.