A PVD apparatus can be operated in a cleaning mode to remove material from an electrically conductive feature formed on a semiconductor substrate. The semiconductor substrate with the electrically conductive feature formed thereon is positioned on a substrate support in a chamber of the PVD apparatus. A shutter is deployed within the chamber to divide the chamber into a first compartment in which the semiconductor substrate and the substrate support are positioned, and a second compartment in which a target of the PVD apparatus is positioned. A first plasma is generated in the first compartment to remove material from the electrically conductive feature and a second plasma is simultaneously generated in the second compartment to clean the target.

Disclosed is a substrate treating apparatus, including: a process chamber in which an inner space for treating a substrate is formed; an ion blocker for dividing the inner space into a plasma generating space and a treatment space; a substrate support unit for supporting a substrate in the treatment space; an exhaust unit for exhausting the treatment space; an anneal source positioned above the ion blocker and transmitting energy for annealing to the substrate through the ion blocker; and a gas supply unit for supplying process gas to the plasma generating space, in which the ion blocker includes: a body which is shaped like a disk, is made of a material through which microwaves are transmittable, and is formed with a plurality of through-holes; and a transparent conductive oxide film provided on at least one of an upper surface and a lower surface of the body in a first thickness or less.

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 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.

A cleaning method is provided. In the cleaning method, residues of elements of a group for a common semiconductor material in a chamber are removed with plasma of a halogen-containing gas. Residues of metal elements of groups 12 and 13 and groups 14 and 15 in the chamber are removed with plasma of a hydrocarbon-containing gas. A C-containing material in the chamber is removed with plasma of an O-containing gas. Further, the removing with the plasma of the halogen-containing gas, the removing with the plasma of the hydrocarbon-containing gas, and the removing with the plasma of the O-containing gas are performed in that order or the removing with the plasma of the hydrocarbon-containing gas, the removing with the plasma of the O-containing gas, and the removing with the plasma of the halogen-containing gas are performed in that order X times where X≥1.

The present invention provides a method for cleaning a component for use in an ultra-high vacuum. The method may comprise the steps of placing the component to be cleaned in a vacuum furnace chamber; plasma cleaning the component at a temperature of greater than about 80° C.; and evacuating the chamber to a pressure of less than about 10E-5 mbar. Apparatus for performing such methods and kits comprising said components are also provided.

A method for removing etchant byproduct from an etch reactor and discharging a substrate from an electrostatic chuck of the etch reactor is provided. A substrate may be electrostatically secured to an electrostatic chuck within a chamber of an etch reactor. A first plasma may be provided into the chamber to etch the substrate, causing an etchant byproduct to be generated. After the etching is complete, a second plasma may be provided into the chamber, wherein the second plasma is an oxygen containing plasma. The etchant byproduct may be removed and the first substrate may be discharged using the second plasma. The first substrate may be removed from the chamber and a second substrate may be inserted into the chamber without first performing an in-situ cleaning between the removal of the first substrate and the insertion of the second substrate.

A processing method includes: disposing a workpiece in a processing container of a processing apparatus, and maintaining an inside of the processing container in a vacuum state; providing a cluster nozzle in the processing container; supplying a cluster generating gas to the cluster nozzle and adiabatically expanding the cluster generating gas in the cluster nozzle, thereby generating gas clusters; generating plasma in the cluster nozzle to ionize the gas clusters and injecting the ionized gas clusters onto the workpiece; supplying a reactive gas to the cluster nozzle and exposing the reactive gas to the plasma such that the reactive gas becomes monomer ions or radicals; and supplying the monomer ions or radicals to the processing container, thereby exerting a chemical reaction on a substance present on a surface of the workpiece.

In one exemplary embodiment, a substrate processing method is provided. This substrate processing method comprises the steps of: providing a substrate including a metal compound film and a mask defining an opening on the metal compound film to a plasma processing chamber; and etching the metal compound film by forming a plasma from a first processing gas including a boron- and halogen-containing gas and a hydrogen-containing gas.