There is disclosed an improved leak checking method which can accurately test a sealing performance of a substrate holder more than conventional leak check techniques. The leak checking method includes: holding a substrate with a substrate holder, the substrate holder including a first holding member and a second holding member, the second holding member having an opening through which a surface of the substrate is exposed; pressing a sealing projection of the second holding member against the surface of the substrate when holding the substrate with the substrate holder; covering the surface of the substrate, exposed through the opening, and the sealing projection with a sealing cap; forming a hermetic space between the sealing cap and the substrate holder; introducing a pressurized gas into the hermetic space; and detecting a decrease in pressure of the pressurized gas in the hermetic space.

A chemical bath system includes a reactor tank configured to store a chemical bath solution including at least one organic element, and an organics removing chamber assembly. The organics removing chamber assembly includes at least one sub-chamber that delivers the chemical bath solution from a high-pressure section of a bath circuit to a low-pressure section. The organics removing chamber assembly modifies an amount of the at least one organic element as the chemical bath solution flows therethrough. The chemical bath system further includes an analysis/dosing controller. The analysis/dosing controller outputs a control signal that controls the organics removing chamber assembly to modify the amount of the at least one organic element in the chemical bath solution based on a comparison between an actual amount of the at least one organic element in the chemical bath solution and a desired amount of the at least one organic element.

The treatment system provides a feature that may reduce cost of the electrochemical plating process by reusing the virgin makeup solution in the spent electrochemical plating bath. The treatment system provides a rotating filter shaft which receives the spent electrochemical plating bath and captures the additives and by-products created by the additives during the electrochemical plating process. To capture the additives and the by-products, the rotating filter shaft includes one or more types of membranes. Materials such as semi-permeable membrane are used to capture the used additives and by-products in the spent electrochemical plating bath. The treatment system may be equipped with an electrochemical sensor to monitor a level of additives in the filtered electrochemical plating bath.

The treatment system provides a feature that may reduce cost of the electrochemical plating process by reusing the virgin makeup solution in the spent electrochemical plating bath. The treatment system provides a rotating filter shaft which receives the spent electrochemical plating bath and captures the additives and by-products created by the additives during the electrochemical plating process. To capture the additives and the by-products, the rotating filter shaft includes one or more types of membranes. Materials such as semi-permeable membrane are used to capture the used additives and by-products in the spent electrochemical plating bath. The treatment system may be equipped with an electrochemical sensor to monitor a level of additives in the filtered electrochemical plating bath.

An electroplating apparatus includes: an electroplating bath including an anode region, in which an anode electrode is arranged, a cathode region and a membrane; a head unit including a contact ring holding a wafer and configured so that a first cathode potential is applied to the contact ring during an electroplating process; a reverse potential electrode arranged adjacent to the membrane and configured so that a second cathode potential is applied to the reverse potential electrode during the electroplating process, and a reverse cathode potential is applied to the reverse potential electrode during a rinsing process; and a power supply unit configured to apply the first cathode potential and the second cathode potential during the electroplating process, and further configured to apply the reverse cathode potential and a reverse anode potential to the anode electrode during the rinsing process.

A method for removing rare earth impurities from a nickel-electroplating solution by adding a rare earth compound to the nickel-electroplating solution containing rare earth impurities, keeping the electroplating solution at 60 C. or higher for a certain period of time, and then removing precipitate generated by the heating from the nickel-electroplating solution together with the added rare earth compound by sedimentation and/or filtration.

A method for removing rare earth impurities from a nickel-electroplating solution by adding a rare earth compound to the nickel-electroplating solution containing rare earth impurities, keeping the electroplating solution at 60 C. or higher for a certain period of time, and then removing precipitate generated by the heating from the nickel-electroplating solution together with the added rare earth compound by sedimentation and/or filtration.

A semiconductor manufacturing apparatus including: a first device; a first calculation circuit that calculates one or more feature quantities of the first device from detected physical quantities; and a failure prediction circuit that determines a portion of model data with a minimum deviation between the measured feature quantities vector comprising the measured one or more feature quantities and a feature quantities vector comprising one or more feature quantities at each time in the plurality of pieces of model data, and calculates a predicted time until failure from a difference between the failure time point in the determined piece of model data and a point in time in the determined piece of model data at which the deviation between the measured feature quantities vector and the feature quantities vector at each time of the plurality of portions of model data is the minimum; and stops the receiving of a new substrate to prevent an introduction of defects on the new substrate.

The present technology includes methods for rinsing an electroplating apparatus, a component thereof, and/or a substrate. The method includes removing at least a portion of a bath solution having a first pH from an electroplating bath. The method includes filtering the removed bath solution through a nanofiltration membrane, forming a permeating containing a recycled rinse agent, and a retentate. The method includes transferring the recycled rinse agent to the one or more nozzles and rinsing the electroplating apparatus, component thereof, and/or substrate. The method includes where the recycled rinse agent is characterized by a second pH, where the second pH varies from the first pH by less than or about 5.

The present technology includes methods for rinsing an electroplating apparatus, a component thereof, and/or a substrate. The method includes removing at least a portion of a bath solution having a first pH from an electroplating bath. The method includes filtering the removed bath solution through a nanofiltration membrane, forming a permeating containing a recycled rinse agent, and a retentate. The method includes transferring the recycled rinse agent to the one or more nozzles and rinsing the electroplating apparatus, component thereof, and/or substrate. The method includes where the recycled rinse agent is characterized by a second pH, where the second pH varies from the first pH by less than or about 5.