A substrate processing apparatus is disclosed. Exemplary substrate processing apparatus includes a plurality of reaction chambers; a shared remote plasma unit; a plurality of first cleaning gas lines configured to fluidly couple the shared remote plasma unit to the reaction chambers; and a cleaning gas source to provide the shared remote plasma unit with a cleaning gas; wherein each of the first cleaning gas lines is provided with a valve and is connected to a sidewall of the reaction chamber.

A method of forming features over a semiconductor substrate is provided. The method includes supplying a gas mixture over a surface of a substrate at a continuous flow rate. A first radio frequency (RF) signal is delivered to an electrode while the gas mixture is supplied at the continuous flow rate to deposit a polymer layer over the surface of the substrate. The surface of the substrate includes an oxide containing portion and a nitride containing portion. A second RF signal is delivered to the electrode while continuously supplying the gas mixture at the continuous flow rate to selectively etch the oxide containing portion relative to the nitride containing portion.

A substrate processing apparatus that processes a substrate using particles, includes a conveyance mechanism configured to convey the substrate along a conveyance surface, a particle source configured to emit particles, a rotation mechanism configured to make the particle source pivot about a rotation axis, and a movement mechanism configured to move the particle source such that a distance between the particle source and the conveyance surface is changed.

Interconnect structures and methods and apparatuses for forming the same are disclosed. In an embodiment, a method includes supplying a process gas to a process chamber; igniting the process gas into a plasma in the process chamber; reducing a pressure of the process chamber to less than 0.3 mTorr; and after reducing the pressure of the process chamber, depositing a conductive layer on a substrate in the process chamber.

Exemplary semiconductor processing chambers may include a gasbox including a first plate having a first surface and a second surface opposite to the first surface. The first plate of the gasbox may define a central aperture that extends from the first surface to the second surface. The first plate may define an annular recess in the second surface. The first plate may define a plurality of apertures extending from the first surface to the annular recess in the second surface. The gasbox may include a second plate characterized by an annular shape. The second plate may be coupled with the first plate at the annular recess to define a first plenum within the first plate.

A method and apparatus for processing a substrate are described herein. The methods and apparatus described enable the raising and lowering of a shadow ring within a process chamber either simultaneously with or separately from a plurality of substrate lift pins. The shadow ring is raised and lowered using a shadow ring lift assembly and may be raised to a pre-determined height above the substrate during a radical treatment operation. The shadow ring lift assembly may also raise and lower the plurality of substrate lift pins to enable both the shadow ring and the substrate lift pins to be raised to a transfer position when the substrate is being transferred into or out of the process chamber.

A film forming system comprises a chamber, a stage, a holder, a cathode magnet, a shield, a first moving mechanism, and a second moving mechanism. The chamber provides a processing space. The stage is provided in the processing space and configured to support a substrate. The holder is configured to hold a target that is provided in the processing space. The cathode magnet is provided outside the chamber with respect to the target. The shield has a slit and is configured to block particles released from the target around the slit. The first moving mechanism is configured to move the shield between the stage and the target along a scanning direction substantially parallel to a surface of the substrate mounted on the stage. The second moving mechanism is configured to move the cathode magnet along the scanning direction.

A rotary plasma reactor system is provided. In another aspect, a plasma reactor is rotatable about a generally horizontal axis within a vacuum chamber. A further aspect employs a plasma reactor, a vacuum chamber, and an elongated electrode internally extending within a central area of the reactor. Yet another aspect employs a plasma reactor for use in activating, etching and/or coating tumbling workpiece material.

A substrate support including a body, a heating element, a first radio frequency filter, and a second radio frequency filter. The body is configured to support a substrate. The heating element is at least partially implemented in a first portion of the body. The first radio frequency filter is connected to an input of the heating element and at least partially implemented in a second portion of the body and connected to the heating element by a first via. The second radio frequency filter is connected to an output of the heating element and at least partially implemented in the second portion or a third portion of the body.

Provided is an apparatus for processing a substrate, which includes a chamber having a processing space in which a process of depositing a thin-film on a substrate is performed and a structure which is installed to expose at least one surface to the processing space and in which a coating layer made of a polymer forming at least one of covalent bond and double bond at an end tail is formed on the surface exposed to the processing space.

Thus, the substrate processing apparatus in accordance with an exemplary embodiment may restrict or prevent particle generation and substrate pollution generation caused by a thin-film deposited in the chamber. Also, a period of cleaning the chamber and a structure or a component in the chamber may be extended. Thus, a product yield rate and an apparatus operation efficiency may improve.