Abstract: A metal layer formed on a wafer, the wafer having a center portion and an edge portion, is electropolished by aligning a nozzle and the wafer to position the nozzle adjacent to the center portion of the wafer. The wafer is rotated. As the wafer is rotated, a stream of electrolyte is applied from the nozzle onto a portion of the metal layer adjacent to the center portion of the wafer to begin to electropolish the portion of the metal layer with a triangular polishing profile to initially expose an underlying layer underneath the metal layer at a point.

Abstract: An apparatus for detecting the end-point of an electropolishing process of a metal layer formed on a wafer includes an end-point detector. The end-point detector is disposed adjacent the nozzle used to electropolish the wafer. In one embodiment, the end-point detector is configured to measure the optical reflectivity of the portion of the wafer being electropolished.

Abstract: In forming a layer of a semiconductor wafer, a dielectric layer is deposited on the semiconductor wafer. The dielectric layer includes material having a low dielectric constant. Recessed and non-recessed areas are formed in the dielectric layer. A metal layer is deposited on the dielectric layer to fill the recessed areas and cover the non-recessed areas. The metal layer is then electropolished to remove the metal layer covering the non-recessed areas while maintaining the metal layer in the recessed areas.

Abstract: An apparatus for detecting the end-point of an electropolishing process of a metal layer formed on a wafer (1004) includes an end-point detector. The end-point detector is disposed adjacent the nozzle (1008) used to electropolish the wafer. In one embodiment, the end-point detector is configured to measure the optical reflectivity of the portion of the wafer being electropolished.

Abstract: In forming a layer of a semiconductor wafer, a dielectric layer is deposited on the semiconductor wafer. The dielectric layer includes material having a low dielectric constant. Recessed and non-recessed areas are formed in the dielectric layer. A metal layer is deposited on the dielectric layer to fill the recessed areas and cover the non-recessed areas. The metal layer is then electropolished to remove the metal layer covering the non-recessed areas while maintaining the metal layer in the recessed areas.

Abstract: In one aspect of the present invention, an exemplary method is provided for electroplating a conductive film on a wafer. The method includes electroplating a metal film on a semiconductor structure having recessed regions and non-recessed regions within a first current density range before the metal layer is planar above recessed regions of a first density, and electroplating within a second current density range after the metal layer is planar above the recessed regions. The second current density range is greater than the first current density range. In one example, the method further includes electroplating in the second current density range until the metal layer is planar above recessed regions of a second density, the second density being greater than the first density, and electroplating within a third current density range thereafter.

Abstract: A metal layer formed on a semiconductor wafer is adaptively electropolished. A portion of the metal layer is electropolished, where portions of the metal layer are electropolished separately. Before electropolishing the portion, a thickness measurement of the portion of the metal layer to be electropolished is determined. The amount that the portion is to be electropolished is adjusted based on the thickness measurement. A metal layer formed on a semiconductor wafer is polished, where the metal layer is formed on a barrier layer, which is formed on a dielectric layer having a recessed area and a non-recessed area, and where the metal layer covers the recessed area and the non-recessed areas of the dielectric layer. The metal layer is polished to remove, the metal layer covering the non-recessed area. The metal layer in the recessed area is polished to a height below the non-recessed area, where the height is equal to or greater than a thickness of the barrier layer.

Abstract: In one aspect of the present invention, exemplary apparatus and methods are provided for electropolishing and/or electroplating processes for semiconductor wafers. One exemplary apparatus includes a cleaning module having an edge clean assembly (930) to remove metal residue on the bevel or edge portion of a wafer (901). The edge cleaning apparatus includes a nozzle head (1030) configured to supply a liquid and a gas to a major surface of the wafer, and supplies the gas radially inward of the location the liquid is supplied to reduce the potential of the liquid from flowing radially inward to the metal film formed on the wafer.

Abstract: An apparatus for electropolishing a wafer includes a wafer chuck and a stationary jet. The wafer chuck is configured to rotate and translate the wafer. The stationary jet is configured to apply an electrolyte to the wafer when the wafer is translated and rotated by the wafer chuck.

Abstract: A metal layer formed on a surface of a wafer is electropolished using a wafer chuck and a moveable nozzle. The surface on which the metal layer is formed is the same surface on which features of devices are formed. The wafer chuck is configured to rotate the wafer when the wafer is placed on top of the wafer chuck. The moveable nozzle is disposed vertically above the wafer when the wafer is placed on top of the wafer chuck. The moveable nozzle is configured to move from a first position to apply a stream of electrolyte to a first portion of the metal layer to a second position to apply the stream of electrolyte to a second portion of the metal layer when the wafer is rotated by the wafer chuck, where the first and second portions of the metal layer are located at different radial positions on the wafer.

Abstract: A wafer chuck for holding a wafer during electropolishing and/or electroplating of the wafer includes a top section, a bottom section, and a spring member. In accordance with one aspect of the present invention, the top section and the bottom section are configured to receive the wafer for processing. The spring member is disposed on the bottom section and configured to apply an electric charge to the wafer. In accordance with another aspect of the present invention, the spring member contacts a portion of the outer perimeter of the wafer. In one alternative configuration of the present invention, the wafer chuck further includes a seal member to seal the spring member from the electrolyte solution used in the electropolishing and/or electroplating process.

Abstract: A wafer chuck for holding a wafer during electropolishing and/or electroplating of the wafer includes a top section, a bottom section, and a spring member. In accordance with one aspect of the present invention, the top section and the bottom section are configured to receive the wafer for processing. The spring member is disposed on the bottom section and configured to apply an electric charge to the wafer. In accordance with another aspect of the present invention, the spring member contacts a portion of the outer perimeter of the wafer. In one alternative configuration of the present invention, the wafer chuck further includes a seal member to seal the spring member from the electrolyte solution used in the electropolishing and/or electroplating process.

Abstract: A wafer chuck assembly for holding a wafer during electroplating and/or electropolishing of the wafer includes a wafer chuck for receiving the wafer. The wafer chuck assembly also includes an actuator assembly for moving the wafer chuck between a first and a second position. When in the first position, the wafer chuck is opened. When in the second position, the wafer chuck is closed.

Abstract: In electropolishing a metal layer on a semiconductor wafer, a dielectric layer is formed on the semiconductor wafer. The dielectric layer is formed with a recessed area and a non-recessed area. A plurality of dummy structures are formed within the recessed areas where the dummy structures are inactive areas configured to increase the planarity of a metal layer subsequently formed on the dielectric layer. A metal layer is then formed to fill the recessed area and cover the non-recessed area and the plurality of dummy structures. The metal layer is then electropolished to expose the non-recessed area.

Abstract: A wafer chuck for holding a wafer during electropolishing and/or electroplating of the wafer includes a top section, a bottom section, and a spring member. In accordance with one aspect of the present invention, the top section and the bottom section are configured to receive the wafer for processing. The spring member is disposed on the bottom section and configured to apply an electric charge to the wafer. In accordance with another aspect of the present invention, the spring member contacts a portion of the outer perimeter of the wafer. In one alternative configuration of the present invention, the wafer chuck further includes a seal member to seal the spring member from the electrolyte solution used in the electropolishing and/or electroplating process.

Abstract: An apparatus for detecting the end-point of an electropolishing process of a metal layer formed on a wafer includes an end-point detector. The end-point detector is disposed adjacent the nozzle used to electropolish the wafer. In one embodiment, the end-point detector is configured to measure the optical reflectivity of the portion of the wafer being electropolished.

Abstract: An electropolishing apparatus for polishing a metal layer formed on a wafer (31) includes an electrolyte (34), a polishing receptacle (100), a wafer chuck (29), a fluid inlet (5, 7, 9), and at least one cathode (1, 2, 3). The wafer chuck (29) holds and positions the wafer (31) within the polishing receptacle (100). The electrolyte (34) is delivered through the fluid inlet (5, 7, 9) into the polishing receptacle (100). The cathode (1, 2, 3) then applies an electropolishing current to the electrolyte to electropolish the wafer (31). In accordance with one aspect of the present invention, discrete portions of the wafer (31) can be electropolished to enhance the uniformity of the electropolished wafer.

Abstract: An electropolishing apparatus for polishing a metal layer formed on a wafer (31) includes an electrolyte (34), a polishing receptacle (100), a wafer chuck (29), a fluid inlet (5, 7, 9), and at least one cathode (1, 2, 3). The wafer chuck (29) holds and positions the wafer (31) within the polishing receptacle (100). The electrolyte (34) is delivered through the fluid inlet (5, 7, 9) into the polishing receptacle (100). The cathode (1, 2, 3) then applies an electropolishing current to the electrolyte to electropolish the wafer (31). In accordance with one aspect of the present invention, discrete portions of the wafer (31) can be electropolished to enhance the uniformity of the electropolished wafer.

Abstract: An apparatus for plating a conductive film directly on a substrate with a barrier layer on top includes anode rod (1) placed in tube (109), and anode rings (2), and (3) placed between cylindrical walls (107) and (105), (103) and (101), respectively. Anodes (1), (2), and (3) are powered by power supplies (13), (12), and (11), respectively. Electrolyte (34) is pumped by pump (33) to pass through filter (32) and reach inlets of liquid mass flow controllers (LMFCs) (21), (22), and (23). Then LMFCs (21), (22) and (23) deliver electrolyte at a set flow rate to sub-plating baths containing anodes (3), (2) and (1), respectively. After flowing through the gap between wafer (31) and the top of the cylindrical walls (101), (103), (105), (107) and (109), electrolyte flows back to tank (36) through spaces between cylindrical walls (100) and (101), (103) and (105), and (107) and (109), respectively.

Abstract: A wafer chuck for holding a wafer during electropolishing and/or electroplating of the wafer includes a top section, a bottom section, and a spring member. In accordance with one aspect of the present invention, the top section and the bottom section are configured to receive the wafer for processing. The spring member is disposed on the bottom section and configured to apply an electric charge to the wafer. In accordance with another aspect of the present invention, the spring member contacts a portion of the outer perimeter of the wafer. In one alternative configuration of the present invention, the wafer chuck further includes a seal member to seal the spring member from the electrolyte solution used in the electropolishing and/or electroplating process.