Abstract: An electroplating apparatus for electroplating a surface of a wafer is provided. The wafer is capable of being electrically charged as a cathode. The electroplating apparatus includes a plating head capable of being positioned either over or under the surface of a wafer and capable of being electrically charged as an anode. The plating head is capable of enabling metallic plating between the surface of the wafer and the plating head when the wafer and plating head are charged. The plating head further comprises a voltage sensor pair capable of sensing a voltage present between the plating head and the surface of the wafer, and a controller capable of receiving data from the voltage sensor pair. The data received from the voltage sensor pair is used by the controller to maintain a substantially constant voltage to be applied by the anode when the plating head is placed in positions over the surface of the wafer. A method of electroplating a wafer is also provided.

Abstract: An apparatus comprising an electrolyte cell, an anode, and a porous rigid diffuser. The electrolyte cell is configured to receive a substrate to have a metal film deposited thereon. An anode is contained within the electrolyte cell. A porous rigid diffuser is connected to the electrolyte cell and extends across the electrolyte cell. The diffuser is positioned between a location that the substrate is to be positioned when the metal film is deposited thereon and the anode.

Abstract: An electroplating apparatus for depositing a metallic layer on a surface of a wafer is provided. In one example, a proximity head capable of being electrically charged as an anode is placed in close proximity to the surface of the wafer. A plating fluid is provided between the wafer and the proximity head to create localized metallic plating.

Abstract: A method and associated apparatus for electro-chemically depositing a metal film on a substrate having a metal seed layer. The apparatus comprises a substrate holder that holds the substrate. The electrolyte cell receives the substrate in a processing position. The actuator is connected to the substrate holder and adjustably positions the substrate relative to the electrolyte cell. The method involves electro-chemically depositing a metal film on a substrate having a metal seed layer comprising disposing the substrate in an electrolyte cell that is configured to receive the substrate. The method comprises adjustably positioning the substrate relative to the electrolyte cell.

Abstract: An electroplating apparatus for depositing a metallic layer on a surface of a wafer is provided. In one example, a proximity head capable of being electrically charged as an anode is placed in close proximity to the surface of the wafer. A plating fluid is provided between the wafer and the proximity head to create localized metallic plating.

Abstract: Embodiments of the invention provide an electrochemical plating cell. The plating cell includes a fluid basin having an anolyte solution compartment and a catholyte solution compartment, an ionic membrane positioned between the anolyte solution compartment and the catholyte solution compartment, and an anode positioned in the anolyte solution compartment, wherein the ionic membrane comprises a poly tetrafluoroethylene based ionomer.

Abstract: An apparatus comprising an electrolyte cell, an anode, and a porous rigid diffuser. The electrolyte cell is configured to receive a substrate to have a metal film deposited thereon. An anode is contained within the electrolyte cell. A porous rigid diffuser is connected to the electrolyte cell and extends across the electrolyte cell. The diffuser is positioned between a location that the substrate is to be positioned when the metal film is deposited thereon and the anode.

Abstract: Embodiments of the invention generally provide a method and apparatus for plating a metal on a substrate. The electrochemical plating system generally includes a plating cell having an anolyte compartment and a catholyte compartment, the anolyte compartment having an insoluble anode and an anolyte therein. The catholyte compartment generally includes a substrate support member and a catholyte therein. In addition, the plating cell generally includes an ion-exchange membrane disposed between the anolyte compartment and the catholyte compartment and a pump in fluid communication with the anolyte compartment, the pump configured to provide an anolyte to the anolyte compartment having a linear velocity of between about 0.5 cm/sec to about 50 cm/sec. The method generally includes supplying an anolyte solution to an anolyte compartment disposed in a plating cell having an anolyte compartment and a catholyte compartment.

Abstract: A method for immersing a substrate into a processing solution. The method includes connecting a power supply between a conductive layer on the substrate and an electrode positioned in the processing solution, immersing the substrate into the processing solution, and applying an electrical bias to the conductive layer during the immersion.

Abstract: A method and apparatus for immersing a substrate for plating operations. The apparatus generally includes a plating cell configured contain a plating solution therein. The plating cell includes at least one fluid basin, a diffusion plate position in a lower portion of the at least one fluid basin, and an anode positioned below the diffusion plate, the anode and the diffusion plate being positioned in parallel orientation with each other and in a tilted orientation with respect to horizontal. The apparatus further includes a head assembly positioned proximate the plating cell, the head assembly including a base member, an actuator positioned at a distal end of the base member, and a substrate support assembly in mechanical communication with the actuator, the substrate support assembly being configured to support a substrate in the at least one fluid basin for processing in an orientation that is generally parallel to the diffusion plate.

Abstract: An electro-chemical plating system is described. A method is performed by the electro-chemical plating system in which a seed layer formed on a substrate is immersed into an electrolyte solution. In one aspect, a substrate is immersed in the electrochemical plating system by tilting the substrate as it enters the electrolyte solution to limit the trapping or formation of air bubbles in the electrolyte solution between the substrate and the substrate holder. In another aspect, an apparatus is provided for electroplating that comprises a cell, a substrate holder, and an actuator. The actuator can displace the substrate holder assembly in the x and z directions and also tilt the substrate. In another aspect, a method is provided of driving a meniscus formed by electrolyte solution across a surface of a substrate. The method comprises enhancing the interaction between the electrolyte solution meniscus and the surface as the substrate is immersed into the electrolyte solution.

Abstract: An apparatus and associated method for deposition of metal ions contained in an electrolyte solution to form a metal film primarily on a seed layer formed on at least a first side of a substrate. The substrate has a second side that is opposed the first side and an edge joining the first side and the second side. The apparatus comprises a substrate holder system and an electric contact element. The electric contact element physically contacts one of the second side or the edge of the substrate. In one aspect, the substrate is rotated about its vertical axis when the seed layer of substrate is immersed in the electrolyte solution during the metal film deposition. In another aspect, the substrate is not rotated about its vertical axis when the seed layer on the substrate is immersed in the electrolyte solution during the metal film deposition.

Abstract: An apparatus comprising an electrolyte cell, an anode, and a porous rigid diffuser. The electrolyte cell is configured to receive a substrate to have a metal film deposited thereon. An anode is contained within the electrolyte cell. A porous rigid diffuser is connected to the electrolyte cell and extends across the electrolyte cell. The diffuser is positioned between a location that the substrate is to be positioned when the metal film is deposited thereon and the anode.

Abstract: An electro-chemical plating system is described. A method is performed by the electro-chemical plating system in which a seed layer formed on a substrate is immersed into an electrolyte solution. In one aspect, a substrate is immersed in the electrochemical plating system by tilting the substrate as it enters the electrolyte solution to limit the trapping or formation of air bubbles in the electrolyte solution between the substrate and the substrate holder. In another aspect, an apparatus is provided for electroplating that comprises a cell, a substrate holder, and an actuator. The actuator can displace the substrate holder assembly in the x and z directions and also tilt the substrate. In another aspect, a method is provided of driving a meniscus formed by electrolyte solution across a surface of a substrate. The method comprises enhancing the interaction between the electrolyte solution meniscus and the surface as the substrate is immersed into the electrolyte solution.

Abstract: An integrated solder bump deposition method and apparatus that enables solder bumps to be lithographically formed on a substrate. The apparatus comprises a plurality of electrolyte cells, and etch/clean/passthrough station and a reflow chamber.

Abstract: A method of immersing a substrate into electrolyte solution for electroplating, the method comprising connecting an electric source between an anode immersed in the electrolyte solution and a seed layer formed on the substrate. A first voltage level of the seed layer is biased to be equal to, or more positive than, a second voltage level of the anode. The substrate is then immersed into the electrolyte solution.

Abstract: A method of immersing a substrate into electrolyte solution for electroplating, the method comprising connecting an electric source between an anode immersed in the electrolyte solution and a seed layer formed on the substrate. A first voltage level of the seed layer is biased to be equal to, or more positive than, a second voltage level of the anode. The substrate is then immersed into the electrolyte solution.

Abstract: An apparatus and associated method for use in a metal deposition cell during operation. The apparatus includes a perforated anode extending generally horizontally across the entire width of the metal deposition cell. Multiple perforations extend substantially vertically and are arranged to provide a substantially uniform electrolyte flow across the width of the metal deposition cell.

Abstract: An integrated solder bump deposition method and apparatus that enables solder bumps to be lithographically formed on a substrate. The apparatus comprises a plurality of electrolyte cells, and etch/clean/passthrough station and a reflow chamber.

Abstract: Methods and apparatus for forming a conformal conductive layer on a substrate for an electroplating process are provided. In one aspect, a method is provided for processing a substrate including depositing a conductive barrier layer on the substrate, and then depositing a nucleation layer on the conductive barrier layer. The nucleation layer is deposited by depositing a first conductive material on the substrate and then depositing a second conductive material on the first conductive material by an electroless deposition process. The second conductive material may comprise nickel, tin, or combinations thereof. The substrate may then be further processed by electroplating a third conductive material on the second conductive material and/or annealing the substrate.