Abstract: Electroplating systems according to embodiments of the present technology may include a plating chamber configured to deposit metal material onto substrates positioned in the plating chamber. The plating chamber may include a rotor and a vessel. The electroplating systems may include at least one of baffle positioned in the plating chamber. The at least one baffle may define a plurality of slots. The at least one baffle may be configured to limit or prevent fluid from splashing the rotor or the plating chamber during operation of the plating chamber.

Abstract: Embodiments of the present technology include electroplating methods that include providing a first portion of an electrolyte feedstock to a first compartment of an electrochemical cell. The first portion of an electrolyte feedstock may be characterized by an initial metal ion concentration and an initial acid concentration. The methods may include providing a second portion of an electrolyte feedstock to a second compartment of the electrochemical cell. The second compartment and first compartment may be separated by a first membrane. The methods may include providing an acidic solution to a third compartment of the electrochemical cell. The third compartment and second compartment may be separated by a second membrane. The acidic solution may be characterized by an initial acid concentration. The methods may include applying a current to an anode of the electrochemical cell. The anode of the electrochemical cell may be disposed proximate the first compartment and across from the first membrane.

Abstract: Electroplating systems may include an electroplating chamber. The systems may also include a replenish assembly fluidly coupled with the electroplating chamber. The replenish assembly may include a first compartment housing anode material. The first compartment may include a first compartment section in which the anode material is housed and a second compartment section separated from the first compartment section by a divider. The replenish assembly may include a second compartment fluidly coupled with the electroplating chamber and electrically coupled with the first compartment. The replenish assembly may also include a third compartment electrically coupled with the second compartment, the third compartment including an inert cathode.

Abstract: Exemplary electroplating systems may include a vessel. The systems may include a paddle disposed within the vessel. The paddle may be characterized by a first surface and a second surface. The first surface of the paddle may be include a plurality of ribs that extend upward from the first surface. The plurality of ribs may be arranged in a generally parallel manner about the first surface. The paddle may define a plurality of apertures through a thickness of the paddle. Each of the plurality of apertures may have a diameter of less than about 5 mm. The paddle may have an open area of less than about 15%.

Abstract: Electroplating systems may include an electroplating chamber. The systems may also include a replenish assembly fluidly coupled with the electroplating chamber. The replenish assembly may include a first compartment housing anode material. The first compartment may include a first compartment section in which the anode material is housed and a second compartment section separated from the first compartment section by a divider. The replenish assembly may include a second compartment fluidly coupled with the electroplating chamber and electrically coupled with the first compartment. The replenish assembly may also include a third compartment electrically coupled with the second compartment, the third compartment including an inert cathode.

Abstract: Electroplating systems according to embodiments of the present technology may include a plating chamber configured to deposit metal material onto substrates positioned in the plating chamber. The plating chamber may include a rotor and a vessel. The electroplating systems may include at least one of baffle positioned in the plating chamber. The at least one baffle may define a plurality of slots. The at least one baffle may be configured to limit or prevent fluid from splashing the rotor or the plating chamber during operation of the plating chamber.

Abstract: A seal ring for an electrochemical processor does not slip or deflect laterally when pressed against a wafer surface. The seal ring may be on a rotor of the processor, with the seal ring having an outer wall joined to a tip arc through an end. The outer wall may be a straight wall. A relatively rigid support ring may be attached to the seal ring, to provide a more precise sealing dimension. Knife edge seal rings that slip or deflect laterally on the wafer surface may also be used. In these designs, the slipping is substantially uniform and consistent, resulting in improved performance.

Abstract: A seal ring for an electrochemical processor does not slip or deflect laterally when pressed against a wafer surface. The seal ring may be on a rotor of the processor, with the seal ring having an outer wall joined to a tip arc through an end. The outer wall may be a straight wall. A relatively rigid support ring may be attached to the seal ring, to provide a more precise sealing dimension. Knife edge seal rings that slip or deflect laterally on the wafer surface may also be used. In these designs, the slipping is substantially uniform and consistent, resulting in improved performance.

Abstract: A substrate processor uses pressurized gas to create a vortex for lifting and holding a wafer, and to create a vacuum to prevent the wafer from adhering to a contact ring seal after electroplating the wafer. A processor head has a rotor movable into and out of an electrolyte vessel. A backing plate on the rotor includes vortex outlets which create the vortex in the rotor. A vacuum channel adjacent to the perimeter of the rotor applies vacuum to the wafer edges to hold the wafer onto the backing plate. A solenoid or switch in the head has a first position to supply gas flow to the vortex outlets, and a second position to supply gas flow to an aspirator which creates the vacuum in the vacuum channel.

Abstract: A seal ring for an electrochemical processor does not slip or deflect laterally when pressed against a wafer surface. The seal ring may be on a rotor of the processor, with the seal ring having an outer wall joined to a tip arc through an end. The outer wall may be a straight wall. A relatively rigid support ring may be attached to the seal ring, to provide a more precise sealing dimension. Knife edge seal rings that slip or deflect laterally on the wafer surface may also be used. In these designs, the slipping is substantially uniform and consistent, resulting in improved performance.

Abstract: An electroplating apparatus having improved contact deplating features includes a bowl assembly having a bowl for holding an electroplating solution. A head having a rotor including a contact ring and a head motor for rotating the rotor cooperates with the bowl assembly during plating operations. A lift/rotate actuator may be used to move the head to position a sector of the contact ring in a ring slot or opening of a deplating module. Since the deplating is performed within the deplating module, and not within the bowl assembly, the electroplating solution in the bowl assembly is not affected by the deplating process.

Abstract: An electroplating apparatus having improved contact deplating features includes a bowl assembly having a bowl for holding an electroplating solution. A head having a rotor including a contact ring and a head motor for rotating the rotor cooperates with the bowl assembly during plating operations. A lift/rotate actuator may be used to move the head to position a sector of the contact ring in a ring slot or opening of a deplating module. Since the deplating is performed within the deplating module, and not within the bowl assembly, the electroplating solution in the bowl assembly is not affected by the deplating process.

Abstract: A wafer plating apparatus has a rotor in a head including wafer retainers which properly hold a wafer on the rotor in position. A seal on the head seals plating bath liquid away from the edges of the wafer. After plating is completed and the wafer is moved away from the seal, the wafer retainers prevent the wafer from sticking to the seal. The rotor may include a backing plate adapted to support a wafer during processing, with the wafer retainers pivotally attached to the backing plate. Movement of the backing plate relative to a seal may move the wafer retainers between open and closed or engaged positions.

Abstract: A wafer plating apparatus has a rotor in a head including wafer retainers which properly hold a wafer on the rotor in position. A seal on the head seals plating bath liquid away from the edges of the wafer. After plating is completed and the wafer is moved away from the seal, the wafer retainers prevent the wafer from sticking to the seal. The rotor may include a backing plate adapted to support a wafer during processing, with the wafer retainers pivotally attached to the backing plate. Movement of the backing plate relative to a seal may move the wafer retainers between open and closed or engaged positions.

Abstract: A workpiece processor has a process chamber for holding a liquid. A sonic element, such as a megasonic transducer, is positioned to provide sonic energy into the liquid. A workpiece holder is moveable from a first position, wherein a workpiece is held immersed in the liquid, for sonic processing, to a second position where the workpiece is generally aligned with spray nozzles. Process liquids and gases may be sprayed or otherwise provided onto the workpiece, optionally while the workpiece is rotating within the process chamber. A process chamber gas or vapor exhaust assembly prevents escape of process gases or vapors from the processor. The processor can provide both sonic processing, as well as liquid and/or gas chemical processing.