Abstract: A substrate processing system includes: a processing chamber defining a reaction volume; a showerhead including: a stem portion having one end connected adjacent to an upper surface of the processing chamber; and a base portion connected to an opposite end of the stem portion and extending radially outwardly from the stem portion, where the showerhead is configured to introduce gas into the reaction volume; a plasma generator configured to selectively generate RF plasma in the reaction volume; and a collar arranged around the stem portion of the showerhead between the base portion of the showerhead and the upper surface of the processing chamber. The collar includes one or more holes to supply purge gas from an inner cavity of the collar to between the base portion of the showerhead and the upper surface of the processing chamber.

Abstract: A chuck assembly for plasma processing, including: an electrostatic chuck having a substrate support surface on a first side; a facility plate coupled to the electrostatic chuck on a second side; a RF feed defined by a first portion contacting a periphery of the facility plate and a second portion coupled to the first portion, the second portion extending away from the chuck assembly, the first portion being a bowl-shaped section, wherein the second portion connects to the first portion at an opening defined in the bowl-shaped section; wherein the first portion of the RF feed contacts the periphery of the facility plate at a circumference circumference having a radius greater than one-half of a radius of the facility plate, the radius of the circumference being less than the radius of the facility plate; a grounded shield disposed below and surrounding at least a portion of the bowl-shaped section.

Abstract: A process module including a chamber body having a lower chamber and an upper chamber is provided. The lower chamber is configured to mate with the upper chamber along a diagonal interface. An electrode assembly having a substrate support is provided. The electrode assembly is coupled to the upper chamber. A hinge connect couples a first side of the lower chamber to a first side of the upper chamber. The upper chamber is configured to split and open along the diagonal interface and rotate about the hinge connect. The electrode assembly is configured to rotate with the upper chamber in a direction that is away from the lower chamber.

Abstract: A substrate is positioned in exposure to a plasma generation region within a plasma processing chamber. A first plasma is generated within the plasma generation region. The first plasma is configured to cause deposition of a film on the substrate until the film deposited on the substrate reaches a threshold film thickness. The substrate is then exposed to ultraviolet radiation to resolve defects within the film deposited on the substrate. The ultraviolet radiation can be supplied in-situ using either a second plasma configured to generate ultraviolet radiation or an ultraviolet irradiation device disposed in exposure to the plasma generation region. The ultraviolet radiation can also be supplied ex-situ by moving the substrate to an ultraviolet irradiation device separate from the plasma processing chamber. The substrate can be exposed to the ultraviolet radiation in a repeated manner to resolve defects within the deposited film as the film thickness increases.

Abstract: Disclosed are apparatuses and methods for performing atomic layer etching. A method may include modifying one or more surface layers of material on the substrate and exposing the one or more modified surface layers on the substrate to an electron source thereby removing, without using a plasma, the one or more modified surface layers on the substrate. An apparatus may include a processing chamber, a process gas unit, an electron source, and a controller with instructions configured to cause the process gas unit to flow a first process gas to a substrate in a chamber interior, the first process gas is configured to modify one or more layers of material on the substrate, and to cause the electron source to generate electrons and expose the one or more modified surface layers on the substrate to the electrons, the one or more modified surface layers being removed, without using a plasma.

Abstract: A method for operating a substrate processing system includes delivering precursor gas to a chamber using a showerhead that includes a head portion and a stem portion. The head portion includes an upper surface, a sidewall, a lower planar surface, and a cylindrical cavity and extends radially outwardly from one end of the stem portion towards sidewalls of the chamber. The showerhead is connected, using a collar, to an upper surface of the chamber. The collar is arranged around the stem portion. Process gas is flowed into the cylindrical cavity via the stem portion and through a plurality of holes in the lower planar surface to distribute the process gas into the chamber. A purge gas is supplied through slots of the collar into a cavity defined between the head portion and an upper surface of the chamber.

Abstract: A cluster tool assembly includes a vacuum transfer module, a process module having a first side connected to the vacuum transfer module. An isolation valve having a first side and a second side, the first side of the isolation valve coupled to a second side of the process module. A replacement station is coupled to the second side of the isolation valve. The replacement station includes an exchange handler and a part buffer. The part buffer includes a plurality of compartments to hold new or used consumable parts. The process module includes a lift mechanism to enable placement of a consumable part installed in the process module to a raised position. The raised position provides access to the exchange handler to enable removal of the consumable part from the process module and store in a compartment of the part buffer. The exchange handler of the replacement station is configured to provide a replacement for the consumable part from the part buffer back to the process module.

Abstract: IR radiation may be used to examine substrates prior to a fabrication operation in order to adjust processing parameters of the fabrication operation, or to determine features of the substrate. A thermographic image may be collected and provided to a transfer function or machine learning model to determine processing parameters or features. The processing parameters may improve the uniformity of the wafer and/or achieve a desired target feature value.

Abstract: Methods and apparatuses for selectively growing metal-containing hard masks are provided herein. Methods include providing a substrate having a pattern of spaced apart features, each feature having a top horizontal surface, filling spaces between the spaced apart features with carbon-containing material to form a planar surface having the top horizontal surfaces of the features and carbon-containing material, selectively depositing a metal-containing hard mask on the top horizontal surfaces of the features relative to the carbon-containing material, and selectively removing the carbon-containing material relative to the metal-containing hard mask and features.

Abstract: A substrate processing system includes a first chamber including a substrate support. A showerhead is arranged above the first chamber and is configured to filter ions and deliver radicals from a plasma source to the first chamber. The showerhead includes a heat transfer fluid plenum, a secondary gas plenum including an inlet to receive secondary gas and a plurality of secondary gas injectors to inject the secondary gas into the first chamber, and a plurality of through holes passing through the showerhead. The through holes are not in fluid communication with the heat transfer fluid plenum or the secondary gas plenum.

Abstract: Methods for depositing films by atomic layer deposition using cyclic siloxane precursors are provided. Methods involve exposing the substrate to a cyclic siloxane precursor during operation of an atomic layer deposition cycle to form silicon oxide.

Abstract: A ceramic layer is attached to a top surface of a base plate using a bond layer. The ceramic layer has a top surface configured to support a substrate. At least one clamp electrode is positioned within an upper region of the ceramic layer. A primary radiofrequency (RF) power delivery electrode is positioned within the ceramic layer at a location vertically below the at least one clamp electrode such that a region of the ceramic layer between the primary RF power delivery electrode and the at least one clamp electrode is substantially free of other electrically conductive material. A plurality of RF power delivery connection modules is distributed in a substantially uniform manner about a perimeter of the ceramic layer. Each of the RF power delivery connection modules is configured to form an electrical connection from the base plate to the primary RF power delivery electrode at its respective location.

Abstract: Methods, systems, and computer programs are presented for selective deposition of etch-stop layers for enhanced patterning during semiconductor manufacturing. One method includes an operation for adding a photo-resist material (M2) on top of a base material (M1) of a substrate, M2 defining a pattern for etching M1 in areas where M2 is not present above M1. The method further includes operations for conformally capping the substrate with an oxide material (M3) after adding M2, and for gap filling the substrate with filling material M4 after the conformally capping. Further, a stop-etch material (M5) is selectively grown on exposed surfaces of M3 and not on surfaces of M4 after the gap filling. Additionally, the method includes operations for removing M4 from the substrate after selectively growing M5, and for etching the substrate after removing M4 to transfer the pattern into M1. M5 adds etching protection to enable deeper etching into M1.

Abstract: An ElectroStatic Chuck (ESC) including a chucking surface having at least a portion covered with a coating of silicon oxide (SiO2), silicon nitride (Si3N4) or a combination of both. The coating can be applied in situ a processing chamber of a substrate processing tool and periodically removed and re-applied in situ to create fresh coating.

Abstract: Systems and methods for real-time control of temperature within a plasma chamber are described. One of the methods includes sensing a voltage in real time of a rail that is coupled to a voltage source. The voltage source supplies a voltage to multiple heater elements of the plasma chamber. The voltage that is sensed is used to adjust one or more duty cycles of corresponding one or more of the heater elements. The adjusted one or more duty cycles facilitate achieving and maintaining a temperature value within the plasma chamber over time.

Abstract: A quartz structure includes a protective layer comprising yttrium oxide. The quartz structure may be fabricated by: (a) receiving a quartz structure; and (b) coating the quartz structure with a protective layer comprising yttrium oxide to form a part to be used in the plasma reactor. The part has a size and shape adapted for forming a window or injector in a plasma reactor. The protective layer does not substantially change the size or shape of the quartz structure. The part may be installed in the plasma reactor at a location where, during operation, a plasma will contact or be proximate to the part.

Abstract: Tin oxide films are used to create air gaps during semiconductor substrate processing. Tin oxide films, disposed between exposed layers of other materials, such as SiO2 and SiN can be selectively etched using a plasma formed in an H2-containing process gas. The etching creates a recessed feature in place of the tin oxide between the surrounding materials. A third material, such as SiO2 is deposited over the resulting recessed feature without fully filling the recessed feature, forming an air gap. A method for selectively etching tin oxide in a presence of SiO2, SiC, SiN, SiOC, SiNO, SiCNO, or SiCN, includes, in some embodiments, contacting the substrate with a plasma formed in a process gas comprising at least about 50% H2. Etching of tin oxide can be performed without using an external bias at the substrate and is preferably performed at a temperature of less than about 100° C.

Abstract: A method for adjusting a position of a showerhead in a processing chamber includes arranging a substrate that includes a plurality of mandrels on a substrate support in the processing chamber and adjusting a position of the showerhead relative to the substrate support. Adjusting the position of the showerhead includes adjusting the showerhead to a tilted position based on data indicating a correlation between the position of the showerhead and azimuthal non-uniformities associated with etching the substrate. The method further includes, with the showerhead in the tilted position as adjusted based on the data, performing a trim step to etch the plurality of mandrels.

Abstract: Embodiments herein relate to methods, apparatus, and systems for electroplating metal into recessed features using a superconformal fill mechanism that provides relatively faster plating within a feature and relatively slower plating in the field region. Moreover, within the feature, plating occurs faster toward the bottom of the feature compared to the top of the feature. The result is that the feature is filled with metal from the bottom upwards, resulting in a high quality fill without the formation of seams or voids, defects that are likely where a conformal fill mechanism is used. The superconformal fill mechanism relies on the presence of a sacrificial oxidant molecule that is used to develop a differential current efficiency within the feature compared to the field region. Various plating conditions are balanced against one another to ensure that the feature fills from the bottom upwards. No organic plating additives are necessary, though plating additives can be used to improve the process.

Abstract: Disclosed are methods of and apparatuses and systems for depositing a film in a multi-station deposition apparatus. The methods may include: (a) providing a substrate to a first station of the apparatus, (b) adjusting the temperature of the substrate to a first temperature, (c) depositing a first portion of the material on the substrate while the substrate is at the first temperature in the first station, (d) transferring the substrate to the second station, (e) adjusting the temperature of the substrate to a second temperature, and (f) depositing a second portion of the material on the substrate while the substrate is at the second temperature, such that the first portion and the second portion exhibit different values of a property of the material. The apparatuses and systems may include a multi-station deposition apparatus and a controller having control logic for performing one or more of (a)-(f).