The present disclosure provides a shielding mechanism and a thin-film-deposition equipment using the same, wherein the shielding mechanism includes two shield members and a driver. The driver includes a motor and a shaft seal. The motor interconnects the two shield members via the shaft seal, and such that to drive the two shield members to sway in opposite directions and to switch between an open state and a shielding state. Furthermore, each of the two shield members is formed with at least one cavity, for reducing weights thereof and loading of the motor and the driver.

The present disclosure provides a thin-film-deposition equipment, which includes a main body, a carrier and a shielding device, wherein a portion of the shielding device and the carrier are disposed within the main body. The main body includes a reaction chamber, and two sensor areas connected to the reaction chamber, wherein the sensor areas are smaller than the reaction chamber. The shielding device includes a first-shield member, a second-shield member and a driver. The driver interconnects the first-shield member and the second-shield member, for driving the first-shield member and the second-shield member to move in opposite directions. During a deposition process, the two shield members are separate from each other into an open state, and respectively enter the two sensor areas. During a cleaning process, the driver swings the shield members toward each other into a shielding state for covering the carrier.

A device for a plasma processing chamber includes a base, an upper portion attached to the base and extending transverse to the base, and one or more first through holes defined in the base. The one or more first through holes correspond to one or more openings defined in the plasma processing chamber for attaching the device. The device further includes a second through hole defined in the upper portion, and a gauge located in the second through hole, the gauge configured for recording a position of the plasma processing chamber and a shift in the position of the plasma processing chamber.

The present invention relates to an internal chamber processing method, and more particularly, to an internal chamber processing method for performing processing on a chamber and a component inside the chamber. Disclosed is an internal chamber processing method for processing the inside of a chamber in which substrate processing is performed, the method including a pressurizing operation (S100) of raising a pressure inside a chamber to a first pressure (P.sub.1) higher than the atmospheric pressure by using a pressurized gas and a depressurizing operation of lowering the pressure inside the chamber from the first pressure (P.sub.1) to a second pressure (P.sub.2) after the pressurizing operation (S100). The pressurizing operation (S100) and the depressurizing operation (S200) are performed in a state in which a substrate to be processed is removed from the inside of the chamber.

A film forming method includes forming a film by sequentially performing operations for each of a plurality of kinds of reaction gases, the operations being of storing the reaction gas in a storage part to raise a pressure in the storage part to a first pressure and then discharging the reaction gas into the process vessel, while continuously supplying the counter gas, and purging by repeating multiple times operations of storing a purge gas in the storage part provided in the reaction gas supply passage to raise the pressure in the storage part to a second pressure higher than the first pressure, and discharging the purge gas into the process vessel. A flow rate of the counter gas supplied into the process vessel in the purging is smaller than a flow rate of the counter gas supplied into the process vessel in the forming the film.

A system includes a plurality of inlets configured to dispense a gas into an enclosure of a substrate processing system. The enclosure is separate from processing chambers of the substrate processing system that process a semiconductor substrate. The system includes a controller configured to move into the enclosure a robot arm used to transport the semiconductor substrate between the processing chambers of the substrate processing system. The controller is configured to dispense the gas into the enclosure through one or more of the inlets in response to the robot arm being moved into the enclosure of the substrate processing system.

The current disclosure relates to a vapor deposition assembly for depositing material on a substrate. The vapor deposition assembly comprises a treatment chamber for treating susceptors from a deposition chamber that comprises multiple, moveable susceptors. The assembly further comprises a transfer system configured and arranged to move a susceptor between the deposition chamber and the treatment chamber. The disclosure further relates to a method of cleaning as susceptor and to a susceptor treatment apparatus.

A chemical vapor deposition (CVD) apparatus is provided. The CVD apparatus includes a CVD chamber including multiple wall portions. A pedestal is disposed inside the CVD chamber, configured to support a substrate. A gas inlet port is disposed on one of the wall portions and below a substrate support portion of the pedestal. In addition, a gas flow guiding member is disposed inside the CVD chamber, coupled to the gas inlet port, and configured to dispense cleaning gases from the gas inlet port into the CVD chamber.

A processing chamber may include a gas distribution member, a metal ring member below the gas distribution member, and an isolating assembly coupled with the metal ring member and isolating the metal ring member from the gas distribution member. The isolating assembly may include an outer isolating member coupled with the metal ring member. The outer isolating member may at least in part define a chamber wall. The isolating assembly may further include an inner isolating member coupled with the outer isolating member. The inner isolating member may be disposed radially inward from the metal ring member about an central axis of the processing chamber. The inner isolating member may define a plurality of openings configured to provide fluid access into a radial gap between the metal ring member and the inner isolating member.

A cleaning method for a by-product including a refractory material or a metal compound includes a reforming process and an etching process. In the reforming process, a surface of the by-product is reformed using nitrogen-containing gas and hydrogen-containing gas. In the etching process, the reformed surface is etched using halogen-containing gas and inert gas.