Abstract: A non-contact apparatus and method for removing a metal layer from a substrate are provided. The apparatus includes a rotatable anode substrate support member configured to support a substrate in a face-up position and to electrically contact the substrate positioned thereon. A pivotally mounted cathode fluid dispensing nozzle assembly positioned above the anode substrate support member is also provided. A power supply in electrical communication with the anode substrate support member and the cathode fluid dispensing nozzle is provided, and a system controller configured to regulate at least one of a rate of rotation of the anode substrate support member, a radial position of the cathode fluid dispensing nozzle, and an output power of the power supply is provided. The method provides for the removal of a metal layer from a substrate by rotating the substrate in a face up position on a rotatable substrate support member.

Abstract: An improved method and apparatus for adjusting chemistry concentrations and temperatures within a substrate processing tank is provided. A first aspect may include checking the fluid level within the tank, and, if the level is higher than a predetermined upper level, bleeding an amount of fluid from the tank; if the level is lower than a predetermined lower level, flowing an amount of fluid to the tank, and if the level is between the predetermined upper and lower levels, bleeding an amount of fluid from the tank and flowing an amount of fluid to the tank. A second aspect may include flowing water into the tank at a flow rate at least equivalent to the flow rate of water required to achieve a chemistry spike of a predetermined concentration and volume prior to beginning the flow of chemicals. A third aspect may include a method and apparatus for heating or cooling chemistry to a predetermined temperature as the chemistry is recirculated.

Abstract: An improved method and apparatus for adjusting chemistry concentrations and temperatures within a substrate processing tank is provided. A first aspect may include checking the fluid level within the tank, and, if the level is higher than a predetermined upper level, bleeding an amount of fluid from the tank; if the level is lower than a predetermined lower level, flowing an amount of fluid to the tank, and if the level is between the predetermined upper and lower levels, bleeding an amount of fluid from the tank and flowing an amount of fluid to the tank. A second aspect may include flowing water into the tank at a flow rate at least equivalent to the flow rate of water required to achieve a chemistry spike of a predetermined concentration and volume prior to beginning the flow of chemicals. A third aspect may include a method and apparatus for heating or cooling chemistry to a predetermined temperature as the chemistry is recirculated.

Abstract: A Megasonic cleaning apparatus having at least one reflector (e.g., a parabolic or paraboloid reflector) positioned to collect otherwise wasted cleaning energy and redirect that energy to one or a plurality of positions on a wafer's edge is provided. A first embodiment comprises a complex parabolic reflector which has a width greater than that of the wafer and a preferred length approximately equal to the diameter of the wafer, and which is shaped to provide focal points which vary along the length of the parabolic reflector, such that energy striking the reflector at different points along the reflector's length is directed to a plurality of different points along the wafer's edge.

Abstract: A method and apparatus is provided that may protect a fragile component (such as a quartz plate) positioned within a megasonic tank from impact by falling objects. The megasonic tank may include a barrier (such as one or more extended rollers, quartz bars, or a net) that is configured to protect the fragile component.

Abstract: A wafer scrubbing unit includes a mounting assembly for a scrubber brush. The mounting assembly has a rotary flow through tube through which cleaning liquid is delivered to the brush. A stationary tube may be mounted in the bore of the rotary tube. Spinning shields mounted on the rotary tube form labyrinth seals to protect a bearing housing from the cleaning liquid. Bearings for rotatably mounting the rotary tube are mounted within the housing.

Abstract: A magnetically coupled roller assembly is provided. A magnet is positioned on the roller and couples to a roller positioned on a drive assembly. The roller and driver are separated by a chamber wall and magnetically coupled therethrough. A shaft coupled to the roller may be positioned in a pocket formed in the chamber wall, and the roller and driver magnets may be axially offset so as to “pull” the roller toward the interior of the pocket.