A method for monitoring a surface condition of a component includes providing thermal energy to a component, determining a thermal response of the heater in response to providing the thermal energy, and determining a thermal characteristic of the component based on a reference thermal response and the thermal response. The method includes predicting the surface condition of the component based on the thermal characteristic and a predictive analytic model, where the predictive analytic model correlates the thermal characteristic of the component to an estimated surface condition of the component.

In a vacuum processing apparatus, a load lock module includes a housing and substrate holding sections, the housing having first substrate transfer ports formed on one of right and left sides thereof and a second substrate transfer port formed on a rear side thereof, and each substrate holding section being configured to hold a substrate on a right or left side in the housing. Further, a normal pressure transfer chamber extends over or under the housing from one of the right and left sides of the housing to the other one thereof so that each first substrate transfer port is opened. The normal pressure transfer chamber includes a stacked transfer region that is a region overlapping the housing. Further, a normal pressure transfer mechanism transfers the substrate between each substrate holding section and a transfer container carried into each of loading/unloading ports via the stacked transfer region.

A showerhead with an embedded nut is disclosed. The showerhead comprises an embedded nut within a cavity. The nut may be engaged by a bolt through an opening in the cavity to support the showerhead. The apparatus allows for the support of the showerhead without the potential for metal contamination.

A substrate processing system for sequentially processing substrates includes processing chambers, a transfer unit, and a control unit controlling the processing chambers and the transfer unit. The control unit includes a transfer control unit controlling an operation of the transfer unit, a transfer order setting unit setting a transfer order of substrates to the processing chambers, an accumulation unit for accumulating a film thickness of a formed thin film or the number of processed substrates after completion of previous cleaning or previous pre-coating in the processing chambers, a processing chamber priority determination unit for determining priority of processing the substrates in the processing chambers based on predetermined rules, and an execution instruction unit for executing conditioning in the processing chambers. The control unit prevents the substrates from being simultaneously processed in all processing chambers during one cycle of executing conditioning once in each of the processing chambers.

A deposition apparatus including a chamber having a deposition area and a non-deposition area, a gas intake device communicated with the chamber, a gas annulus disposed in the chamber and surrounding the gas intake device, a carrier disposed in the deposition area and a retaining annulus disposed in chamber and surrounding the carrier. The gas intake device is disposed corresponding to the deposition area and configured to draw a process gas into the deposition area. The gas annulus is configured to generate an annular gas curtain in the deposition area. The carrier carries a deposited object, wherein the gas annulus is located between the gas intake device and the carrier. The deposited object is surrounded by the annular gas curtain. The retaining annulus has a plurality of through holes. The retaining annulus is located between the gas annulus and the carrier.

Methods and apparatus for processing substrates are provided herein. In some embodiments, an apparatus for processing substrates includes a chamber body enclosing a processing volume, the chamber body comprising a chamber floor, a chamber wall coupled to the chamber floor, and a chamber lid removably coupled to the chamber wall, wherein at least one of the chamber floor, the chamber wall, and the chamber lid comprise passages for a flow of a thermal control media; a heater plate disposed adjacent to and spaced apart from the chamber floor; a sleeve disposed adjacent to and spaced apart from the chamber wall, the sleeve supported by the heater plate; and a first sealing element disposed at a first interface between the chamber wall and the chamber lid.

The invention concerns a reactor for chemical vapour deposition from first and second precursor gases, the reactor comprising: —a chamber including top and bottom walls and a side wall linking the top and bottom walls, —a support intended for receiving at least one substrate, mounted inside the chamber, and —at least one system for injecting precursor gases, the system comprising an injection head including at least one nozzle for supplying the first precursor gas (41) in a main direction of axis A-A′, the at least one nozzle including: a precursor gas supply conduit (321), and an outlet member (322) generating a substantially annular 43 vortex flow (44) around axis A-A′.

A method and apparatus for reproducing a component of a semiconductor manufacturing apparatus, and a reproduced component are provided. The method may include a preparing step of preparing a damaged component of a semiconductor manufacturing apparatus, a first cleaning step of cleaning the damaged component, a masking step of masking at least one of areas including an undamaged part of the damaged component, a reproduced part forming step of forming a reproduced part on the damaged component using a chemical vapor deposition (CVD), a post-grinding step of grinding the damaged component with the reproduced part, and a second cleaning step of cleaning the damaged component with the reproduced part.

Plasma processing conditions may be changed for localized regions of a substrate. A reactive gas may be maintained in a localized region of a substrate while other regions of the substrate are not exposed to the reactive gas. Thus, plasma conditions may be generated at specific regions of the substrate. A multi-zoned gas injection system may be utilized to direct certain gases in certain regions of the plasma space. Techniques may be provided to maintain these gases in the desired regions, as opposed to the gases spreading across the substrate surface. Reactive gases may be provided in one region while a flow of inert gas is provided in other regions in which it is desired to restrict the effects of the reactive gases. Localized control of the plasma process may be provided as a separate plasma processing step. The localized region of the substrate may be the substrate edge.

Certain embodiments of the present disclosure relate to chamber liners, processing chambers that include chamber liners, and methods of using the same. In one embodiment, a method of operating a processing chamber includes causing a chamber liner within the processing chamber to move to a loading position to allow a substrate to be inserted through an access port of the processing chamber into an interior volume of the processing chamber. The method further includes causing the chamber liner to move to an operation position that blocks the access port after the substrate has been inserted into the interior volume. The method further includes generating a plasma using a cathode assembly.