A method for cleaning a chamber of a substrate processing system includes maintaining the chamber at a first predetermined pressure and, without a substrate present within the chamber, providing, from a fluid source via a nozzle assembly, a fluid, and injecting the fluid into the chamber via the nozzle assembly. The fluid source is maintained at a second predetermined pressure that is greater than the first predetermined pressure. Injecting the fluid into the chamber maintained at the first predetermined pressure causes the fluid to aerosolize into a mixture of gas and solid particles.

A method for recycling a substrate holder adapted to receive a substrate for at least one deposition step of a layer of a material on the substrate also leading to the depositing of a layer of a material on the substrate holder, the method including implanting ion species through a receiving surface of the substrate holder so as to form at least one buried weakened plane delimiting a thin film underneath the receiving surface of the substrate holder, exfoliating the thin film from the substrate holder so as to break up the thin film, and removing a stack including at least one layer of a material deposited on the thin film resulting from the at least one deposition step of the layer of a material on the substrate.

A method for recycling a substrate process component of a processing chamber is provided. In one example, the recycling process includes retrieving a reference dimension for the substrate process component. The substrate process component includes a side wall having a bottom surface, an outer surface, a pre-defined wall thickness between the bottom surface and the outer surface, and a residue layer. The reference dimension corresponds to the pre-defined wall thickness. The recycling process includes machining the substrate process component with a mechanical cutting tool. The machining includes securing the substrate process component to a work piece holder and passing the mechanical cutting tool across the outer surface in a machining operation controlled by a controller to remove the residue layer. The controller uses the reference dimension to control the machining operation so that the substrate process component has the reference dimension after removal of the residue layer.

Systems and methods for cleaning a showerhead are described. One of the systems includes a support section and a press plate located above the support section to be supported by the support section. The system further includes a cleaning layer located above the press plate. The cleaning layer moves to clean a showerhead. The support section contacts an arm of a spindle assembly for movement with movement of the arm.

A method of cleaning residue containing ruthenium (Ru) residue on at least one surface of a component of a semiconductor processing chamber is provided. The residue is exposed to a Ru cleaning composition comprising at least one of hypochlorite and 03 based chemistries, wherein the Ru cleaning composition removes the Ru residue.

The innovative method is for removing a silicon carbide layer from a bulk piece; the bulk piece comprises a graphite substrate underlying the silicon carbide layer; the method comprises in succession the steps of: a) submerging the bulk piece in a first solution containing nitric acid, b) submerging the bulk piece in a second solution containing hydrofluoric acid and an oxidizing agent, and typically c) submerging the bulk piece in a third solution containing preferably only or essentially deionized water until the layer detaches from the piece; this method can advantageously be used to clean components of an epitaxial reactor e.g. after their use in the reactor in silicon carbide deposition processes.

A method for exfoliation of deposited material off a work piece may comprise: immersing the work piece in an ultrasonic bath and applying ultrasonic energy, wherein the ultrasonic bath contains a fluid either held at a constant temperature within the range from greater than room temperature to less than the fluid boiling point, or the fluid is cycled over a T chosen within the range between room temperature and less than the fluid boiling point, wherein the temperature is chosen to provide a significant CTE mismatch between the layer and the work piece in order to promote exfoliation of the layer off the work piece, and wherein process time in the ultrasonic bath is within a range from several seconds up to 120 minutes for loosening the layer; cleaning the work piece by rinsing with liquids; and drying the work piece. A system is described for running the exfoliation process.

The present disclosure provides a powder-atomic-layer-deposition device with knocker, which mainly includes a vacuum chamber, a shaft seal, a drive unit and a knocker. The drive unit is connected to the rear wall of the vacuum chamber via the shaft seal, for driving the vacuum chamber to rotate. The shaft seal includes an outer tube and an inner tube, wherein the inner tube is disposed within the containing space of the outer tube. The inner tube is disposed with a gas-extracting pipeline and a gas-inlet pipeline therein, wherein the gas-extracting pipeline is for gas extraction of the vacuum chamber, the gas-inlet pipeline is for transferring a precursor gas into the vacuum chamber. The knocker and the vacuum chamber are adjacent to each other, for knocking the vacuum chamber to prevent powders within the reacting space from sticking to the inner surface of the vacuum chamber.

Disclosed herein is a delivery device comprising a chamber; a gas inlet; a gas outlet; and a dip tube contained within the chamber and having an upper portion and a lower portion, the upper portion of the dip tube being in fluid communication with the gas inlet and being operative to permit the entry of a carrier gas; the lower portion of the dip tube extending into the chamber, the lower portion of the dip tube terminating in an outlet end; and a sleeve; where the sleeve has a first end and a second end; the first end being in an interference fit with the lower portion of the dip tube; and where the sleeve vibrates upon being subjected to a disturbance.

A reactor for coating particles includes a stationary vacuum chamber to hold a bed of particles to be coated, a vacuum port in an upper portion of the chamber, a chemical delivery system configured to inject a reactant or precursor gas into a lower portion of the chamber, a paddle assembly, and a motor to rotate a drive shaft of the paddle assembly. The lower portion of the chamber forms a half-cylinder. The paddle assembly includes a rotatable drive shaft extending through the chamber along the axial axis of the half cylinder, and a plurality of paddles extending radially from the drive shaft such that rotation of the drive shaft by the motor orbits the plurality of paddles about the drive shaft.