A method of etching a film of a substrate is provided. The substrate includes an underlying region, the film and a mask. The film is provided on the underlying region. The mask is provided on the film. The method comprises performing main etching on the film. The main etching is plasma etching of the film and exposes at least a part of the underlying region. The method further comprises forming a protective layer on at least a side wall surface of the mask after the performing of the main etching. A material of the protective layer is different from a material of the film. The method further comprises performing over-etching on the film after the forming of the protective layer. The over-etching is plasma etching of the film.

An end effector for moving workpieces and replaceable parts within a system for processing workpieces. The end effector may include an arm portion extending between a first arm end and a second arm end along the axial direction. The end effector may further include a spatula portion extending between a first spatula end and a second spatula end, the first spatula end being adjacent the second arm end. Further, the end effector may include a first support member extending outwardly from the spatula portion, a second support member extending outwardly from the spatula portion, and a shared support member extending outwardly from the arm portion. The shared support member and the first support member together to support workpieces of a first diameter, and the shared support member and the second support member together support replaceable parts of a second diameter.

Exemplary methods of forming a coating of material on a substrate may include forming a plasma of a first precursor and an oxygen-containing precursor. The first precursor and the oxygen-containing precursor may be provided in a first flow rate ratio. The methods may include depositing a first layer of material on the substrate. While maintaining the plasma, the methods may include adjusting the first flow rate ratio to a second flow rate ratio. The methods may include depositing a second layer of material on the substrate.

A substrate processing apparatus comprises a chamber member that defines an interior volume that has an aspect ratio. The chamber member comprises a pair of laterally opposing inlet walls and a loading port. Each of the pair of laterally opposing inlet walls has an inlet port configured to receive output from a remote plasma source. The loading port is arranged between the pair of inlet walls, configured to allow passage of a substrate into the interior volume.

Embodiments of the present invention provide a plasma chamber design that allows extremely symmetrical electrical, thermal, and gas flow conductance through the chamber. By providing such symmetry, plasma formed within the chamber naturally has improved uniformity across the surface of a substrate disposed in a processing region of the chamber. Further, other chamber additions, such as providing the ability to manipulate the gap between upper and lower electrodes as well as between a gas inlet and a substrate being processed, allows better control of plasma processing and uniformity as compared to conventional systems.

A method and apparatus for dosage measurement and monitoring in an ion implantation system is disclosed. In one embodiment, a transferring system, includes: a vacuum chamber, wherein the vacuum chamber is coupled to a processing chamber; a shaft coupled to a ball screw, wherein the ball screw and the shaft are configured in the vacuum chamber; and a vacuum rotary feedthrough, wherein the vacuum rotary feedthrough comprises a magnetic fluid seal so as to provide a high vacuum sealing, and wherein the vacuum rotary feedthrough is configured through a first end of the vacuum chamber and coupled to the ball screw so as to provide a rotary motion on the ball screw.

A method for selectively etching a stack with respect to a mask is provided. An atomic layer etch is provided to at least partially etch the stack, wherein the atomic layer etch forms at least some residue. An ion beam is provided to etch the stack, wherein the ion beam etch removes at least some of the residue from the atomic layer etch.

A method of etching a film of a substrate is provided. The substrate includes an underlying region, the film and a mask. The film is provided on the underlying region. The mask is provided on the film. The method includes performing main etching on the film. The main etching is plasma etching of the film and exposes at least a part of the underlying region. The method further includes forming a protective layer on at least a side wall surface of the mask after the performing of the main etching. A material of the protective layer is different from a material of the film. The method further includes performing over-etching on the film after the forming of the protective layer. The over-etching is plasma etching of the film.

A storage container for accommodating an annular member having a notch on at least one of an outer circumference and an inner circumference thereof is disclosed. The storage container comprises a base plate on which the annular member is placed. The base plate comprises a plurality of guide pins that protrude from the base plate and are configured to position the annular member. The plurality of guide pins include a pin engaged with the notch.

A system including a control plate disposed within a processing chamber. The control plate includes a set of plasma elements designed to independently expose a substrate disposed within the processing chamber to plasma related fluxes. The control plate is designed to independently activate the set of plasma elements. When activated the associated plasma elements expose the substrate to the plasma related fluxes and when not activated the associated plasma elements prevent exposure of the substrate to the plasma related fluxes. The control plate is designed to perform individual time-dependent activation of the set of plasma elements to selectively expose the substrate to the plasma related fluxes.