Embodiments of the disclosure relate to apparatus and method for a tunable plasma process within a plasma processing chamber. In one embodiment of the disclosure, a heater assembly for a plasma processing chamber is disclosed. The heater assembly includes a resistive heating element, a first lead coupling the resistive heating element to an RF filter and a tunable circuit element operable to adjust an impedance between the resistive heating element and the RF filter. Another embodiment provides a method for controlling a plasma process in a plasma processing chamber by forming a plasma from a process gas present inside the plasma processing chamber and adjusting an impedance between a resistive heating element and an RF filter coupled between the resistive heating element and a power source for the resistive heating element, while the plasma is present in the plasma processing chamber.

A method includes depositing a second dielectric layer over a first dielectric layer, depositing a third dielectric layer over the second dielectric layer, patterning a plurality of first openings in the third dielectric layer, etching the second dielectric layer through the first openings to form second openings in the second dielectric layer, performing a plasma etching process directed at the second dielectric layer from a first direction, the plasma etching process extending the second openings in the first direction, and etching the first dielectric layer through the second openings to form third openings in the first dielectric layer.

Aspects of the disclosure relate to apparatus for the fabrication of waveguides. In one example, an angled ion source is utilized to project ions toward a substrate to form a waveguide which includes angled gratings. In another example, an angled electron beam source is utilized to project electrons toward a substrate to form a waveguide which includes angled gratings. Further aspects of the disclosure provide for methods of forming angled gratings on waveguides utilizing an angled ion beam source and an angled electron beam source.

The present disclosure provides an apparatus including a chamber body and a lid defining a volume therein. The apparatus includes a substrate support disposed in the volume opposite the lid. The substrate support includes a support body disposed on a stem, and a ground plate disposed between the support body and the stem. A top flange is coupled to a lower peripheral surface the ground plate and a bottom flange is coupled to a bottom of the chamber body. The bottom flange and the top flange is coupled to one another with a plurality of straps, each of the straps having a first end coupled to the bottom flange and a second end coupled to the top flange.

A portable container is provided for handling an implant. The container comprises a sealed compartment enclosing a fluid of a pre-defined composition and at least one implant configured to be installed in a live subject. The container may comprise at least one electrode made of an electrical conductive material, electrically associated with an electric conductor outside the sealed compartment and configured for applying a plasma generating electric field inside the sealed compartment. An apparatus for plasma treatment of an implant and having an activation device is further provided. The activation device comprises a slot configured to receive a portable container, and an electrical circuit configured to be electrically associated with at least one electrode. The electrical circuit is configured to provide to the at least one electrode electric power suitable for applying a plasma generating electric field in the sealed compartment, when the portable container is disposed in the slot.

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.

The embodiments herein relate to methods and apparatus for etching features in semiconductor substrates. In a number of cases, the features may be etched while forming a spin-torque-transfer random access memory (STT-RAM) device. In various embodiments, the substrate may be cooled to a low temperature via a cooled substrate support during particular processing steps. The cooled substrate support may have beneficial impacts in terms of reducing the degree of diffusion-related damage in a resulting device. Further, the use of a non-cooled substrate support during certain other processing steps can likewise have beneficial impacts in terms of reducing diffusion-related damage, depending on the particular step. In some implementations, the cooled substrate support may be used in a process to preferentially deposit a material (in some cases a reactant) on certain portions of the substrate.

Exemplary semiconductor processing chambers may include a gasbox. The chambers may include a substrate support. The chambers may include a blocker plate positioned between the gasbox and the substrate support. The blocker plate may define a plurality of apertures through the plate. The chambers may include a faceplate positioned between the blocker plate and the substrate support. The faceplate may be characterized by a first surface facing the blocker plate and a second surface opposite the first surface. The faceplate may be characterized by a central axis. The faceplate may define a plurality of apertures through the faceplate distributed in a number of rings. Each ring of apertures may include a scaled increase in aperture number from a ring radially inward. A radially outermost ring of apertures may be characterized by a number of apertures reduced from the scaled increase in aperture number.

A method includes forming a mask layer over a target layer. A first etching process is performed on the mask layer to form a first opening and a second opening in the mask layer. A second etching process is performed on the mask layer to reduce an end-to-end spacing between the first opening and the second opening. The first etching process and the second etching process have different anisotropy properties. A pattern of the mask layer is transferred to the target layer.

A plasma source (100), comprises an outer face (10) with an aperture (14) for delivering a plasma from the aperture. A transport mechanism is configured to transport a substrate (11) and the plasma source relative to each other parallel to the outer face, with a substrate surface to be processed in parallel with at least a part of the outer face that contains the aperture. First (4-1) and second tile (4-2) are arranged within a first plane of a working electrode (22) with neighbouring edges (12) bordering a first plasma collection space (6-1) and a third tile (4-3) is arranged in a second plane of the working electrode parallel to the first plane such that the third tile overlaps neighbouring edges in the first plane. At least one of the working and counter electrodes comprises a local modification (13,15) near said neighbouring edges to increase a plasma delivery to the aperture compensating for loss of plasma collection due to the neighbouring edges.