The present disclosure relates to heating a substrate in a rapid thermal processing (RTP) chamber. The chamber may contain a rotatable assembly configured to accommodate and rotate the substrate while a heat source inside the RTP chamber applies heat to the substrate. The rotatable assembly is partially disposed outside the RTP chamber. A seal may formed around the rotatable assembly and maintain a vacuum inside the RTP chamber while the rotatable assembly rotates. The rotatable assembly may configured to accommodate various-sized substrates.

A vapor deposition device is provided that can correct a positional offset of a carrier in a rotation direction relative to a wafer when the vapor deposition device is viewed in a plan view. The vapor deposition device includes a load-lock chamber provided with a holder for supporting the carrier, and the carrier and the holder are provided with a correction mechanism that corrects a position of the carrier in a rotation direction when the vapor deposition device is viewed in a plan view.

Embodiments of the present disclosure generally relate to methods, apparatus, and systems for maintaining film modulus within a predetermined modulus range. In one implementation, a method of processing substrates includes introducing one or more processing gases to a processing volume of a processing chamber, and depositing a film on a substrate supported on a substrate support disposed in the processing volume. The method includes supplying simultaneously a first radiofrequency (RF) power and a second RF power to one or more bias electrodes of the substrate support. The first RF power includes a first RF frequency and the second RF power includes a second RF frequency that is less than the first RF frequency. A modulus of the film is maintained within a predetermined modulus range.

A heating device includes a heating assembly. The heating assembly includes a ventilation structure configured to blow gas to an edge of a to-be-processed workpiece carried by the heating device. The heating device further includes a base arranged on a side of the heating assembly away from a heating surface of the heating assembly. A mounting space is formed between the base and the heating assembly. The heating device also includes a cooling mechanism arranged in the mounting space, located at a position corresponding to an edge area of the heating surface, and configured to cool the heating assembly.

A measurement device and method for a semiconductor structure are provided. The measurement device for the semiconductor structure includes a bearing platform, a clamping mechanism, and an image acquisition system. The clamping mechanism is installed on the bearing platform and includes a clamp disposed along a vertical direction. The clamp is configured to clamp the semiconductor structure such that the semiconductor structure is clamped with a to-be-measured surface facing a side. The image acquisition system is disposed by a side of the clamping mechanism, and is configured to acquire a three-dimensional morphology of the semiconductor structure from the side.

The present invention relates to a substrate processing apparatus for processing a substrate. The substrate processing apparatus (1) includes a controller (90). The controller (90) rotates the substrate (W) at a second speed, after rotating the substrate (W) at a first speed. The controller (90) supplies a dry fluid from a dry fluid nozzle (30) onto the substrate (W) for predetermined time after rotating the substrate (W) at the second speed, and while rotating the substrate (W) at a third speed. The controller (90) moves a dry fluid nozzle (30) from a center of the substrate (W) toward a peripheral portion of the substrate (W) while continuing to supply the dry fluid from the dry fluid nozzle (30).

A first ceramic member and a second ceramic member are joined together at a lower joining temperature while reducing the loss of bond strength. A method for producing a semiconductor production device component includes a step of providing a first ceramic member including an AlN-based material, a step of providing a second ceramic member including an AlN-based material, and a step of joining the first ceramic member and the second ceramic member to each other by thermally pressing the first ceramic member and the second ceramic member to each other via a joint agent including Eu.sub.2O.sub.3, Gd.sub.2O.sub.3 and Al.sub.2O.sub.3 disposed between the first ceramic member and the second ceramic member.

A heater assembly and method of controlling the heater assembly is provided. The heater assembly includes a resistive heater and a substrate, and the resistive heater comprises a plurality of heating zones disposed along a perimeter of the substrate. Each of the plurality of heating zones are independently controllable such that azimuthal temperature control of the heater assembly is provided. The plurality of resistive heating elements may be connected in series and have a common ground electrical lead. In the alternative, the plurality of resistive heating elements may each have a ground electrical lead and be isolated from each other.

Embodiments of the present disclosure generally relate to apparatus and methods utilized in the manufacture of semiconductor devices. More particularly, embodiments of the present disclosure relate to a substrate processing chamber, and components thereof, for forming semiconductor devices.

An assembly for use in a process chamber for depositing a film on a wafer. The assembly includes a pedestal having a pedestal top surface extending from a central axis of the pedestal to an outer edge, the pedestal top surface having a plurality of wafer supports for supporting a wafer. A pedestal step having a step surface extending from a step inner diameter towards the outer edge of the pedestal. A focus ring rests on the step surface and having a mesa extending from an outer diameter of the focus ring to a mesa inner diameter. A shelf steps downwards from a mesa surface at the mesa inner diameter, and extends between the mesa inner diameter and an inner diameter of the focus ring. The shelf is configured to support at least a portion of a wafer bottom surface of the wafer at a process temperature.