Abstract: Embodiments of the present technology may include a method of etching. The method may include mixing plasma effluents with a gas in a first section of a chamber to form a first mixture. The method may also include flowing the first mixture to a substrate in a second section of the chamber. The first section and the second section may include nickel plated material. The method may further include reacting the first mixture with the substrate to etch a first layer selectively over a second layer. In addition, the method may include forming a second mixture including products from reacting the first mixture with the substrate.

Abstract: Exemplary semiconductor processing systems may include a processing chamber, and may include a remote plasma unit coupled with the processing chamber. Exemplary systems may also include an adapter coupled with the remote plasma unit. The adapter may include a first end and a second end opposite the first end. The adapter may define an opening to a central channel at the first end, and the central channel may be characterized by a first cross-sectional surface area. The adapter may define an exit from a second channel at the second end, and the adapter may define a transition between the central channel and the second channel within the adapter between the first end and the second end. The adapter may define a third channel between the transition and the second end of the adapter, and the third channel may be fluidly isolated from the central channel and the second channel.

Abstract: Implementations of the present disclosure relate to an electrode assembly for a processing chamber. In one implementation, the electrode assembly includes a cathode electrode having an inner volume and a ground anode electrode spaced apart from the cathode electrode. A first etchant gas is introduced through the cathode electrode and into the inner volume. The first etchant gas is ionized within the inner volume. The ionized first etchant gas is filtered to allow only radicals to flow from the inner volume into a mixing volume formed within the ground anode electrode. The mixing volume is separated from the inner volume by a gas injection ring. The radicals from the first etchant gas are mixed and reacted with a second etchant gas in molecular phase, which is introduced through the ground anode electrode into a sidewall of the gas injection ring before entering the mixing volume in an evenly distributed manner.

Abstract: Semiconductor systems and methods may include a semiconductor processing chamber having a gas box defining an access to the semiconductor processing chamber. The chamber may include a spacer characterized by a first surface with which the gas box is coupled, and the spacer may define a recessed ledge on an interior portion of the first surface. The chamber may include a support bracket seated on the recessed ledge that extends along a second surface of the spacer. The chamber may also include a gas distribution plate seated on the support bracket.

Abstract: Semiconductor systems and methods may include a semiconductor processing chamber having a gas box defining an access to the semiconductor processing chamber. The chamber may include a spacer characterized by a first surface with which the gas box is coupled, and the spacer may define a recessed ledge on an interior portion of the first surface. The chamber may include a support bracket seated on the recessed ledge that extends along a second surface of the spacer. The chamber may also include a gas distribution plate seated on the support bracket.

Abstract: A plasma source includes a first electrode and a second electrode having respective surfaces, and an insulator that is between and in contact with the electrodes. The electrode surfaces and the insulator surface substantially define a plasma cavity. The insulator surface defines one or more grooves configured to prevent deposition of material in a contiguous form on the insulator surface. A method of generating a plasma includes introducing one or more gases into a plasma cavity defined by a first electrode, a surface of an insulator that is in contact with the first electrode, and a second electrode that faces the first electrode. The insulator surface defines one or more grooves where portions of the insulator surface are not exposed to a central region of the cavity. The method further includes providing RF energy across the first and second electrodes to generate the plasma within the cavity.

Abstract: A method of preparing an aluminum tube for use as a gas line includes plating a nickel alloy throughout internal surfaces of the aluminum tube, to form the gas line. A gas line for transport of gases includes an aluminum tube with a nickel alloy coating throughout internal surfaces of the tube. A plasma processing apparatus includes at least two process chambers for exposing a workpiece to a plasma, and a gas line that supplies, from one or more inlet ports, one or more gases for generating the plasma to two outlet ports. Each of the two outlet ports interfaces to a respective one of the process chambers, and the gas line includes an aluminum tube with a nickel alloy coated internal surface.

Abstract: A plasma source includes a first electrode and a second electrode having respective surfaces, and an insulator that is between and in contact with the electrodes. The electrode surfaces and the insulator surface substantially define a plasma cavity. The insulator surface defines one or more grooves configured to prevent deposition of material in a contiguous form on the insulator surface. A method of generating a plasma includes introducing one or more gases into a plasma cavity defined by a first electrode, a surface of an insulator that is in contact with the first electrode, and a second electrode that faces the first electrode. The insulator surface defines one or more grooves where portions of the insulator surface are not exposed to a central region of the cavity. The method further includes providing RF energy across the first and second electrodes to generate the plasma within the cavity.

Abstract: Implementations of the disclosure generally provide an improved pedestal heater for a processing chamber. The pedestal heater includes a temperature-controlled plate having a first surface and a second surface opposing the first surface. The temperature-controlled plate includes an inner zone comprising a first set of heating elements, an outer zone comprising a second set of heating elements, the outer zone surrounding the inner zone, and a continuous thermal choke disposed between the inner zone and the outer zone, and a substrate receiving plate having a first surface and a second surface opposing the first surface, the second surface of the substrate receiving plate is coupled to the first surface of the temperature-controlled plate. The continuous thermal choke enables a very small temperature gradient to be created and manipulated between the inner zone and the outer zone, allowing center-fast or edge-fast etching profile to achieve on a surface of the substrate.

Abstract: Implementations of the present disclosure relate to an electrode assembly for a processing chamber. In one implementation, the electrode assembly includes a cathode electrode having an inner volume and a ground anode electrode spaced apart from the cathode electrode. A first etchant gas is introduced through the cathode electrode and into the inner volume. The first etchant gas is ionized within the inner volume. The ionized first etchant gas is filtered to allow only radicals to flow from the inner volume into a mixing volume formed within the ground anode electrode. The mixing volume is separated from the inner volume by a gas injection ring. The radicals from the first etchant gas are mixed and reacted with a second etchant gas in molecular phase, which is introduced through the ground anode electrode into a sidewall of the gas injection ring before entering the mixing volume in an evenly distributed manner.

Abstract: A wafer pedestal of a semiconductor apparatus is provided. The wafer pedestal is capable of supporting a substrate. The wafer pedestal includes a pedestal having at least one purge opening configured to flow a purge gas and at least one chucking opening configured to chuck the substrate over the pedestal. The pedestal includes a sealing band disposed between the at least one purge opening and the at least one chucking opening. The sealing band is configured to support the substrate.

Abstract: Systems and chambers for processing dielectric films on substrates are described. Vertical combo chambers include two separate processing chambers vertically arranged in a processing stack. A top processing chamber is configured to process the substrate at relatively low substrate temperature. A robot is configured to remove a substrate from the top processing chamber and change height before placing the substrate in a bottom processing chamber. The bottom processing chamber is configured to anneal the substrate to further process the dielectric film. The vertical stacking increases the number of processing chambers which can be included on a single processing system. The separation of the bottom (annealing or curing) chamber and the top chamber allows the top chamber to remain at a low temperature which hastens the start of a process conducted on a new wafer transferred into the top chamber.

Abstract: A substrate support comprising a top ceramic plate providing a substrate support surface for supporting a substrate during substrate processing, a substrate pedestal having coolant channels formed therein and a thermoelectric deck sandwiched between the top ceramic plate and substrate pedestal. The thermoelectric deck includes a plurality of embedded thermoelectric elements that can either heat or cool the substrate support surface.

Abstract: A method for manufacturing a faceplate of a semiconductor apparatus is provided. The method includes selecting a size of a tool in response to a predetermined specification of a predetermined gas parameter. The tool is used to form the holes within the faceplate. A first gas parameter of the holes of the faceplate is measured by an apparatus to determine if the measured first gas parameter of the holes of the faceplate is within the predetermined specification.

Abstract: A wafer pedestal of a semiconductor apparatus is provided. The wafer pedestal is capable of supporting a substrate. The wafer pedestal includes a pedestal having at least one purge opening configured to flow a purge gas and at least one chucking opening configured to chuck the substrate over the pedestal. The pedestal includes a sealing band disposed between the at least one purge opening and the at least one chucking opening. The sealing band is configured to support the substrate.