The present disclosure concerns an array of chemical and electrochemical treatment cells. The cells include electrochemical cells that individually include a plating tank, a power supply, and an anode. A flight bar for supporting a cathode is moved from one tank to another for treating and plating a cathode surface. Within an electrochemical tank, the power supply operates a circuit with metal ions being eroded from the anode and being deposited onto the cathode surface. A plating apparatus is configured to simultaneously provide mechanical support, a cathodic connection, and agitation to a cathode in a plating tank. The plating apparatus includes an agitator which rotates the cathode about a fixed pivot connection to provide motion along a lateral axis and a vertical axis.

The present disclosure concerns an array of chemical and electrochemical treatment cells. The cells include electrochemical cells that individually include a plating tank, a power supply, and an anode. A flight bar for supporting a cathode is moved from one tank to another for treating and plating a cathode surface. Within an electrochemical tank, the power supply operates a circuit with metal ions being eroded from the anode and being deposited onto the cathode surface. A plating apparatus is configured to simultaneously provide mechanical support, a cathodic connection, and agitation to a cathode in a plating tank. The plating apparatus includes an agitator which rotates the cathode about a fixed pivot connection to provide motion along a lateral axis and a vertical axis.

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.

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.

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.

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.

In some examples, an electroplating apparatus is provided for depositing a metal layer on a substrate. An example electroplating apparatus comprises a plating cell to receive a plating solution, an electrode, a counter electrode, a substrate holding fixture, a resistive element, and a de-bubbler device supportable rotatably adjacent the resistive element to generate or direct a flow of plating solution through the resistive element to release trapped bubbles.

In some examples, an electroplating apparatus is provided for depositing a metal layer on a substrate. An example electroplating apparatus comprises a plating cell to receive a plating solution, an electrode, a counter electrode, a substrate holding fixture, a resistive element, and a de-bubbler device supportable rotatably adjacent the resistive element to generate or direct a flow of plating solution through the resistive element to release trapped bubbles.

Disclosed herein are systems and methods for electroplating nickel which employ substantially sulfur-free nickel anodes. The methods may include placing a semiconductor substrate in a cathode chamber of an electroplating cell having an anode chamber containing a substantially sulfur-free nickel anode, contacting an electrolyte solution having reduced oxygen concentration with the substantially sulfur-free nickel anode contained in the anode chamber, and electroplating nickel from the electrolyte solution onto the semiconductor substrate placed in the cathode chamber. The electroplating systems may include an electroplating cell having an anode chamber configured for holding a substantially sulfur-free nickel anode, a cathode chamber, and a substrate holder within the cathode chamber configured for holding a semiconductor substrate. The systems may also include an oxygen removal device arranged to reduce oxygen concentration in the electrolyte solution as it is flowed to the anode chamber.

Disclosed herein are systems and methods for electroplating nickel which employ substantially sulfur-free nickel anodes. The methods may include placing a semiconductor substrate in a cathode chamber of an electroplating cell having an anode chamber containing a substantially sulfur-free nickel anode, contacting an electrolyte solution having reduced oxygen concentration with the substantially sulfur-free nickel anode contained in the anode chamber, and electroplating nickel from the electrolyte solution onto the semiconductor substrate placed in the cathode chamber. The electroplating systems may include an electroplating cell having an anode chamber configured for holding a substantially sulfur-free nickel anode, a cathode chamber, and a substrate holder within the cathode chamber configured for holding a semiconductor substrate. The systems may also include an oxygen removal device arranged to reduce oxygen concentration in the electrolyte solution as it is flowed to the anode chamber.