A heat treatment apparatus includes a control device. The control device includes a heat treatment control unit that controls a heat treatment performed on a processing target accommodated in a processing container, according to a process condition, a cleaning control unit that controls a cleaning process on deposits adhering to the processing container due to the heat treatment, a cumulative film thickness specification unit that specifies a value of a cumulative film thickness of the deposits adhering to the processing container, based on the process condition for the heat treatment, and a temperature correction unit that corrects a temperature of the heat treatment based on a temperature correction amount corresponding to the value of the cumulative film thickness and a frequency of the cleaning process.

A carrier plate for receiving a wafer includes a pocket defined in a middle section on a top surface of the carrier plate and has a surface diameter. The pocket defines a substrate support region. A retaining feature of the carrier plate is defined at an outer edge of the pocket. A tapered portion of the carrier plate extends from the retaining feature to an outer diameter. The tapered portion is configured to receive a focus ring. A bottom surface of the carrier plate is configured to sit over a pedestal that is used in a process chamber. A plurality of wafer supports is disposed on a top surface of the substrate support region to support the wafer, when received.

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 system and method for controlling electrostatic clamping of multiple platens on a spinning disk is disclosed. The system comprises a semiconductor processing system, such as a high energy implantation system. The semiconductor processing system produces a spot ion beam, which is directed to a plurality of workpieces, which are disposed on a spinning disk. The spinning disk comprises a rotating central hub with a plurality of platens. The plurality of platens may extend outward from the central hub and workpieces are electrostatically clamped to the platens. The central hub provides the electrostatic clamping voltages to each of the plurality of platens. Further, the plurality of platens may also be capable of rotation about an axis orthogonal to the rotation axis of the central hub. The central hub controls the rotation of each of the platens. Power connections and communications are provided to the central hub via the spindle assembly.

A system for controlling of wafer bow in plasma processing stations is described. The system includes a circuit that provides a low frequency RF signal and another circuit that provides a high frequency RF signal. The system includes an output circuit and the stations. The output circuit combines the low frequency RF signal and the high frequency RF signal to generate a plurality of combined RF signals for the stations. Amount of low frequency power delivered to one of the stations depends on wafer bow, such as non-flatness of a wafer. A bowed wafer decreases low frequency power delivered to the station in a multi-station chamber with a common RF source. A shunt inductor is coupled in parallel to each of the stations to increase an amount of current to the station with a bowed wafer. Hence, station power becomes less sensitive to wafer bow to minimize wafer bowing.

A wafer transfer system can include a wafer gripper for picking and placing semiconductor devices. In an embodiment, the wafer gripper can include a first portion, a second portion and a laminate between the first and second portion. In one embodiment, the first portion can comprise glass or tempered glass, where the first portion having at least one vacuum hole and is configured to receive the semiconductor device. In an embodiment, the second portion can include glass or tempered glass, the second portion having configured to use low air pressure from a closed vacuum to vacuum a wafer. In an embodiment, the laminate can bond the first portion to the second portion.

Apparatus and method for processing a plurality of substrates in a batch processing chamber are described. The apparatus comprises a susceptor assembly, a lift assembly and a rotation assembly. The susceptor assembly has a top surface and a bottom surface with a plurality of recesses in the top surface. Each of the recesses has a lift pocket in the recess bottom. The lift assembly including a lift plate having a top surface to contact the substrate. The lift plate is connected to a lift shaft that extends through the susceptor assembly and connects to a lift friction pad. The rotation assembly has a rotation friction pad that contacts the lift friction pad. The rotation friction pad is connected to a rotation shaft and can be vertically aligned with the lift friction pad.

A wafer susceptor includes a plurality of grooves and a convex structure disposed in one groove of the plurality of grooves. The convex structure is asymmetrical, and a convex part of the convex structure is far away from a circle center of a wafer susceptor. The surface temperature of a portion of a substrate far away from the circle center of the wafer susceptor is increased. That is, the temperature of the convex position is basically the same as that of other positions on the substrate, the surface of the entire substrate is heated more uniformly, and thus the wavelength of an epitaxial wafer formed on the substrate is also more uniform, and the quality of the epitaxial wafer is promoted.

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 apparatus includes a vacuum chamber, a wafer transfer mechanism, a first gas source, a second gas source and a reuse gas pipe. The vacuum chamber is divided into at least three reaction regions including a first reaction region, a second reaction region and a third reaction region. The wafer transfer mechanism is structured to transfer a wafer from the first reaction region to the third reaction region via the second reaction region. The first gas source supplies a first gas to the first reaction region via a first gas pipe, and a second gas source supplies a second gas to the second reaction region via a second gas pipe. The reuse gas pipe is connected between the first reaction region and the third reaction region for supplying an unused first gas collected in the first reaction region to the third reaction region.