Abstract: Frequency tuning for a matchless plasma source is described. To perform the frequency tuning, current is measured at an output of an amplification circuit of the matchless plasma source after a change in a frequency of operation of the matchless plasma source. Upon determining that the current has increased with the change in the frequency of operation, the frequency of operation is further changed until the current has decreased. When the current has decreased, the changed frequency of operation is further modified to be an operational frequency. When the matchless plasma source operates at the operational frequency, the current at the output of the amplification circuit is maximized.

Abstract: A substrate processing system includes a first power source configured to supply plasma having a first power level, a second power source configured to supply plasma having a second power level greater than the first power level, and a controller configured to dose a process chamber with precursor. The first power level is sufficient to enhance adsorption of the precursor on a surface of a substrate and is insufficient to decompose the precursor that is adsorbed. The controller is further configured to remove a portion of the precursor that does not adsorb onto the substrate from the process chamber while the plasma having the first power level is being supplied and activate the precursor that is adsorbed using plasma having the second power level while the plasma having the first power level is still being supplied. The second power level is sufficient to decompose the precursor that is adsorbed.

Abstract: Silicon oxide, silicon nitride, and silicon oxynitride films may be deposited by thermal atomic layer deposition (thermal ALD) in a single wafer plasma reactor. The single wafer plasma reactor can perform thermal ALD and plasma-enhanced atomic layer deposition (PEALD). Highly conformal films may be deposited at a high deposition rate without damaging or with minimal damage to the substrate using thermal ALD. The substrate may be heated at an elevated temperature during oxidation and/or nitridation. In some implementations, the elevated temperature is between about 500 C and about 750 C. In some implementations, hydrogen and oxygen may be flowed as reactant gases during oxidation, where the hydrogen and oxygen may react in an exothermic reaction to drive formation of oxide.

Abstract: A method of electroplating a metal into features, having substantially different depths, of a partially fabricated electronic device on a substrate is provided. The method includes adsorbing accelerator into the bottom of recessed features; partially filling the features by a bottom up fill mechanism in an electroplating solution; diffusing leveler into shallow features to decrease the plating rate in shallow features as compared to deep features; and electroplating more metal into the features such that the height of metal in deep features is similar to the height of metal in shallow features.

Abstract: Various embodiments include an apparatus to supply precursor gases to a processing tool. In various examples, the apparatus includes a point-of-use (POU) valve manifold that includes a manifold body to couple to a processing chamber of the processing tool. The manifold body has a multiple precursor-gas outlet ports surrounded by an annulus. A purge-gas outlet port of the manifold body is directed substantially toward interior walls of the annulus. For each of multiple precursor gases, the POU-valve manifold further includes: a first valve coupled to the manifold body and a divert valve coupled to the first valve. The first valve can be coupled to a precursor-gas supply and has a separate precursor-gas flow path internal to the manifold body. The divert valve diverts the precursor gas during a period when the precursor gas is not to be directed into the processing chamber by the first valve. Other examples are disclosed.

Abstract: Various embodiments include apparatuses to raise and lower substrates, as used in the semiconductor and allied industries, toward or away from a substrate-holding mechanism (e.g., such as an electrostatic chuck (ESC). In a specific embodiment, a substrate lift-mechanism includes a number of pins to position the substrate above a substrate-holding device. Mid-position sensors are respectively coupled to a corresponding pin. The mid-position sensors monitor an intermediate position of the corresponding pin between a maximum position and a minimum position. Other apparatuses and systems are disclosed.

Abstract: A software emulation system for a gas delivery system of a substrate processing system includes an input/output bus and an emulator bus. An input/output bus adapter includes a switch configured to route data packets from a system controller for the substrate processing system to one of the input/output bus and the emulator bus. A gas delivery system emulator in communication with the emulator bus is configured to receive the data packets from the input/output bus adapter via the emulator bus and perform software-based emulation of a plurality of hardware components of the gas delivery system that are interconnected. The plurality of hardware components are modelled using one or more software models and include a gas source and at least one of a valve and a mass flow controller.

Abstract: Defects on a substrate comprising electronic components can be classified with a computational defect analysis system that may be implemented in multiple stages. For example, a first stage classification engine may process metrology data to produce an initial classification of defects. A second stage classification engine may use the initial classification, along with manufacturing information and/or prior defect knowledge to output probabilities that the defects are caused by one or more potential sources.

Abstract: A substrate processing system for a substrate processing chamber includes a gas delivery system configured to direct process gases toward a substrate support in the substrate processing chamber and a controller. During processing of a substrate arranged on the substrate support the controller is configured to calculate, based on at least one of a position of an edge ring of the substrate support and characteristics of the process gases directed toward the substrate support, a distribution of etch by-product material redeposited onto the substrate during processing and, in response to the calculated distribution, generate control signals to cause an actuator to selectively adjust a position of the edge ring relative to the substrate and cause the gas delivery system to selectively adjust a flow of the process gases.

Abstract: A method comprises depositing a barrier layer on a dielectric layer to prevent oxidation of a metal layer to be deposited by electroplating due to an oxide present in the dielectric layer and depositing a doped liner layer on the barrier layer to bond with the metal layer to be deposited on the liner layer by the electroplating. The dopant forms a protective passivation layer on a surface of the liner layer and dissolves during the electroplating so that the metal layer deposited on the liner layer by the electroplating bonds with the liner layer. The dopant reacts with the dielectric layer and forms a layer of a compound between the barrier layer and the dielectric layer. The compound layer prevents oxidation of the barrier layer and the liner layer due to the oxide present in the dielectric layer and adheres the barrier layer to the dielectric layer.

Abstract: A substrate processing system includes a laser triangulation sensor configured to transmit and receive light through a window of an exterior wall of a substrate processing chamber. A controller is configured to: position the laser triangulation sensor such that the laser triangulation sensor transmits light onto a measurement feature arranged between a first surface of a substrate support and a second surface of a gas distribution device, where the second surface faces the first surface; and while the laser triangulation sensor transmits light onto the measurement feature, determine a first distance between the first and second surfaces based on a difference between: a second distance between the laser triangulation sensor and the first surface measured using the laser triangulation sensor; and a third distance between the laser triangulation sensor and the second surface measured using the laser triangulation sensor.

Abstract: Methods and apparatuses for selective deposition of metal oxides on metal surfaces relative to dielectric surfaces are provided. Selective deposition is achieved by exposing metal and dielectric surfaces to a blocking reagent capable of forming a hydrolyzable bond with metal while forming a non hydrolyzable bond with the dielectric, and dipping the surfaces in water to cleave the hydrolyzable bond and leave a blocked surface on the dielectric surface, followed by depositing metal oxide selectively on the metal surface relative to the dielectric surface. Blocking reagents are deposited by wet or dry techniques and may include an alkylaminosilane or alkylchlorosilane as examples.

Abstract: Methods and electroplating systems for controlling plating electrolyte concentration on an electrochemical plating apparatus for substrates are disclosed. A method involves: (a) providing an electroplating solution to an electroplating system; (b) electroplating the metal onto the substrate while the substrate is held in a cathode chamber of an electroplating cell of electroplating system; (c) supplying the make-up solution to the electroplating system via a make-up solution inlet; and (d) supplying the secondary electroplating solution to the electroplating system via a secondary electroplating solution inlet. The secondary electroplating solution includes some or all components of the electroplating solution. At least one component of the secondary electroplating solution has a concentration that significantly deviates from its target concentration.

Abstract: Systems and methods for etching different features in a substantially equal manner are described. One of the methods includes applying a low frequency bias signal during a low TCP state and applying a high frequency bias signal during a high TCP state. The application of the low frequency bias signal during the low TCP state facilitates generation of hot neutrals, which are used to increase an etch rate of etching dense features compared to an etch rate for etching isolation features. The application of the high frequency bias signal during the high TCP state facilitates generation of ions to increase an etch rate of etching the isolation features compared to an etch rate of etching the dense features. After applying the low frequency bias signal during the low TCP state and the high frequency bias signal during the high TCP state, the isolation and dense features are etched similarly.

Abstract: A substrate processing tool includes a wafer transport assembly that includes a first wafer transport module and extends along a longitudinal axis of the substrate processing tool. A plurality of process modules includes a first process module and a second process module arranged on opposite sides of the longitudinal axis of the substrate processing tool. Outer sides of the first wafer transport module are coupled to the first and second process modules, respectively. A service tunnel defined below the wafer transport assembly extends along the longitudinal axis from a front end of the substrate processing tool to a rear end of the substrate processing tool below the wafer transport assembly.

Abstract: An apparatus for supporting a wafer during a plasma processing operation includes a pedestal configured to have bottom surface and a top surface and a column configured to support the pedestal at a central region of the bottom surface of the pedestal. An electrical insulating layer is disposed over the top surface of the pedestal. An electrically conductive layer is disposed over the top surface of the electrical insulating layer. At least three electrically conductive support structures are distributed on the electrically conductive layer. The at least three support structures are configured to interface with a bottom surface of a wafer to physically support the wafer and electrically connect to the wafer. An electrical connection extends from the electrically conductive layer to connect with a positive terminal of a direct current power supply at a location outside of the pedestal.

Abstract: A method for conditioning ceramic coating on a part for use in a plasma processing chamber is provided. The ceramic coating is wetted with a solution, wherein the solution is formed by mixing a solvent with an electrolyte, wherein from 1% to 10% of the electrolyte dissociates in the solution. The ceramic coating is blasted with particles. The ceramic coating is rinsed.

Abstract: An assembly used in a process chamber for depositing a film on a wafer. A pedestal assembly includes a pedestal movably mounted to a main frame. A lift pad rests upon the pedestal and moves with the pedestal assembly. A raising mechanism separates the lift pad from the pedestal, and includes a hard stop fixed to the main frame, a roller attached to the pedestal assembly, a slide moveably attached to the pedestal assembly, a lift pad bracket interconnected to the slide and a pad shaft extending from the lift pad, and a lever rotatably attached to the lift pad bracket. The lever rests on the roller when not engaged with the upper hard stop. When the pedestal assembly moves upwards, the lever rotates about a pin when engaging the upper hard stop and roller, and separates the lift pad from the pedestal by a process rotation displacement.

Abstract: Provided herein are methods and systems for reducing roughness of an EUV resist and improving etched features. The methods involve descumming an EUV resist, filling divots of the EUV resist, and protecting EUV resists with a cap. The resulting EUV resist has smoother features and increased selectivity to an underlying layer, which improves the quality of etched features. Following etching of the underlying layer, the cap may be removed.