A semiconductor device manufacturing method, including: mounting substrates on a mounting table within a processing chamber along a rotation direction of the table; starting to supply a first-element-containing gas to a first region in the chamber along the rotation direction, while rotating the table and exhausting the processing chamber; starting to supply a second-element-containing gas to a second region in the chamber; starting to generate, by a plasma generating unit in the second region, plasma of the second-element-containing gas in the second region to have a first activity; and forming a thin film containing first and second elements on the substrates by rotating the table to cause the substrates to sequentially pass through the first and second regions in turn so that a first-element-containing layer is formed in the first region and is modified in the second region by generating plasma having a second activity higher than the first activity.

A substrate processing apparatus includes: a process chamber where a substrate is processed; a substrate support, disposed in the process chamber, where the substrate is placed; a transfer chamber disposed under the process chamber; a partition dividing the process and transfer chambers; a first heating unit disposed in the substrate support to heat the substrate and the process chamber; a second heating unit disposed in the transfer chamber to heat the transfer chamber; a process gas supply unit to supply a process gas into the process chamber; a first cleaning gas supply unit to supply a cleaning gas into the process chamber; a second cleaning gas supply unit to supply the cleaning gas into the transfer chamber; and a control unit to control the first heating unit, the second heating unit, the process gas supply unit, the first cleaning gas supply unit and the second cleaning gas supply unit.

A method of manufacturing a semiconductor device uses a semiconductor manufacturing apparatus including a turn table allowing placement of at least first and second semiconductor substrates and being capable of moving positions of the first and the second semiconductor substrates by turning, a first film forming chamber, and a second film forming chamber. The first and the second film forming chambers are provided with an opening capable of loading and unloading the first and the second semiconductor substrates by lifting and lowering the first and the second semiconductor substrates placed on the turn table. The method includes transferring the first and the second semiconductor substrates between the first and the second film forming chambers by turning the turn fable and lifting and lowering the first and the second semiconductor substrates placed on the turn table; and forming a stack of films above the first and the second semiconductor substrates.

An article, apparatus, and method for detecting an etch rate uniformity in a processing chamber of an electronics processing system is provided. A device is placed in a processing chamber of an electronics processing system. The device includes a first layer deposited on a surface of the device and a second layer deposited on the first layer. The first layer is composed of a first sense material and the second layer is composed of an etch material. During an etch process at the processing chamber, a first amount of time from an initiation of the etch process to a detection of a first indication of completion of etching of the second layer at a first portion of the surface of the device is measured. The etch process etches the second layer of the device based on an initial set of etch parameter settings. A first etch rate of the processing chamber is determined based on the measured first amount of time and a thickness of the second layer. An optimized set of etch parameter settings to be applied at the processing chamber during subsequent etch processes is determined based on the first etch rate of the processing chamber.

A plasma processing system having at least one processing chamber comprising at least two sub-chambers is provided. The two plasma sub-chambers are in plasma flow or gas flow communication through a passage, which is controlled by a gate. The gate may be operated to allow plasma migration between the two sub-chambers to occur at different conductance rates. In one example, the gate comprises two plates with openings through the plates. At least one of the plates may be rotatable relative to the other plates to govern the conductance rate of the plasma from one sub-chamber to the other sub-chamber.

An etching method includes: providing a substrate having a film and a patterned mask on the film; forming a silicon-containing layer including silicon, carbon, and nitrogen on the substrate using a precursor gas containing silicon; and performing a plasma etching on the film. The substrate is placed under a depressurized environment for a time period from a start time point of the step of forming the silicon-containing layer on the substrate to an end time point of the step of performing the plasma etching on the film.

Disclosed are methods of and systems for depositing a film. The methods may include: (a) determining process conditions, including a flow condition of a curtain gas that flows around the periphery of each station in the chamber, for performing film deposition in the chamber, (b) flowing the curtain gas to each station in the chamber during film deposition according to the process conditions determined in (a), (c) determining, during or after (b), an adjusted flow condition of the curtain gas in the chamber to improve substrate nonuniformity, and (d) flowing, after (c), the curtain gas during film deposition according to the adjusted flow condition determined in (c). The systems may include a gas delivery system, a processing chamber, and a controller having control logic for performing one or more of (a)-(d).

A power converter is capable to convert an electrical input power into a bipolar output power and to deliver the bipolar output power to at least two independent plasma processing chambers. The power converter includes a power input port for connection to an electrical power delivering grid, at least two power output ports each for connection to one of the plasma processing chambers, and a controller configured to control the power converter to deliver the bipolar output power to the power output ports, using at least one of control parameters including power, voltage, current, excitation frequency, and threshold for protective measures. The controller includes a virtual power supply for each power output port, and each virtual power supply includes a separate complete set of all fixed and time varying parameters and internal states associated with the operation of the individual power output port.

An exemplary system may include a chamber configured to contain a semiconductor substrate in a processing region of the chamber. The system may include a first remote plasma unit fluidly coupled with a first access of the chamber and configured to deliver a first precursor into the chamber through the first access. The system may still further include a second remote plasma unit fluidly coupled with a second access of the chamber and configured to deliver a second precursor into the chamber through the second access. The first and second access may be fluidly coupled with a mixing region of the chamber that is separate from and fluidly coupled with the processing region of the chamber. The mixing region may be configured to allow the first and second precursors to interact with each other externally from the processing region of the chamber.

Methods are provided for planarizing a patterned substrate in a spatial atomic layer processing system comprising a rotating platen. The patterned substrate may generally include features having higher regions and lower regions. To planarize the patterned substrate, or reduce a height differential between the higher and lower regions, a selective atomic layer etching (ALE) process is disclosed to preferentially form a modified layer on the higher regions of the features by exposing a surface of the patterned substrate to a precursor gas while the rotating platen spins at a high rotational speed. By preferentially forming the modified layer on the higher regions of the features, and subsequently removing the modified layer, the selective ALE process described herein preferentially etches the higher regions of the features to lessen the height differential between the higher and lower regions until a desired planarization of the features is achieved.