A hydrogen-free carbon film polymer lubricating material and a preparation method and use thereof are disclosed. In the method, a graphite target is used as the target material, and a magnetron sputtering deposition is performed on a surface of the polymer substrate, thereby physically depositing and forming a hydrogen-free carbon film on the surface of the polymer substrate, thereby obtaining a hydrogen-free carbon film polymer lubricating material.

The PVD apparatus includes a chamber, a plurality of stages, a first target holder, a power supply mechanism, and a shield. The plurality of stages are provided inside the chamber, and each of the plurality of stages is configured to place at least one substrate on an upper surface thereof. The first target holder is configured to hold at least one target provided for one stage, the target being exposed to a space inside the chamber. The power supply mechanism supplies power to the target via the first target holder. The shield is provided inside the chamber and a part of the shield is disposed between a first stage and a second stage in the plurality of stages, and between a first processing space on the first stage and a second processing space on the second stage.

The PVD apparatus includes a chamber, a plurality of stages, a first target holder, a power supply mechanism, and a shield. The plurality of stages are provided inside the chamber, and each of the plurality of stages is configured to place at least one substrate on an upper surface thereof. The first target holder is configured to hold at least one target provided for one stage, the target being exposed to a space inside the chamber. The power supply mechanism supplies power to the target via the first target holder. The shield is provided inside the chamber and a part of the shield is disposed between a first stage and a second stage in the plurality of stages, and between a first processing space on the first stage and a second processing space on the second stage.

Embodiments of process kits are provided herein. In some embodiments, a process kit, includes: a deposition ring configured to be disposed on a substrate support, the deposition ring comprising: an annular band having an upper surface and a lower surface, the lower surface including a step between a radially inner portion and a radially outer portion, the step extending downward from the radially inner portion to the radially outer portion; an inner lip extending upwards from the upper surface of the annular band and adjacent an inner surface of the annular band, and wherein an outer surface of the inner lip extends radially outward and downward from an upper surface of the inner lip to the upper surface of the annular band; a channel disposed radially outward of the annular band; and an outer lip extending upwardly and disposed radially outward of the channel.

Embodiments of process kits are provided herein. In some embodiments, a process kit, includes: a deposition ring configured to be disposed on a substrate support, the deposition ring comprising: an annular band having an upper surface and a lower surface, the lower surface including a step between a radially inner portion and a radially outer portion, the step extending downward from the radially inner portion to the radially outer portion; an inner lip extending upwards from the upper surface of the annular band and adjacent an inner surface of the annular band, and wherein an outer surface of the inner lip extends radially outward and downward from an upper surface of the inner lip to the upper surface of the annular band; a channel disposed radially outward of the annular band; and an outer lip extending upwardly and disposed radially outward of the channel.

Embodiments of deposition rings for use in a process chamber are provided herein. In some embodiments, a deposition ring includes: an annular body; an inner wall extending upward from an inner portion of the annular body; and an outer wall extending upward form an outer portion of the annular body to define a large deposition cavity between the inner wall and the outer wall, wherein a width of the large deposition cavity is about 0.35 inches to about 0.60 inches, wherein the outer wall includes an outer ledge and an inner ledge raised with respect to the outer ledge.

Embodiments of the present disclosure provide a substrate processing system. In one embodiment, the system includes a chamber, a target disposed within the chamber, a magnetron disposed proximate the target, a pedestal disposed within the chamber, and a first gas injector disposed at a sidewall of the chamber, the first gas injector having a movable gas outlet.

Embodiments of the present disclosure provide a substrate processing system. In one embodiment, the system includes a chamber, a target disposed within the chamber, a magnetron disposed proximate the target, a pedestal disposed within the chamber, and a first gas injector disposed at a sidewall of the chamber, the first gas injector having a movable gas outlet.

Disclosed is a coating made of an organic material on a mold for glass molding. The coating comprises Cr.sub.xW.sub.yN.sub.(1-x-y), where 0.15<x<0.4, and 0.2≤y≤0.45. The coating has excellent high temperature resistance and anti-adhesion properties, thus being a promising coating material for molds.

A chamber for a physical vapor deposition (PVD) apparatus includes a collimator configured to narrow filter sputtered particles into a beam, an electrostatic chuck configured to support a substrate in the chamber, a shield and a chamber plate. The chamber plate includes a nut plate portion having a plurality of nut plates and a plurality of cavities in the chamber plate that are configured to allow gas to ingress and egress, wherein the cavities and nut plates are provided in equal numbers. The chamber is configured to operate at a target pressure, and the number of nut plates and corresponding number of cavities are determined based on the target pressure.