Abstract: Substantially uniform deposition of conductive material on a surface of a substrate, which substrate includes a semiconductor wafer, from an electrolyte containing the conductive material can be provided by way of a particular device which includes first and second conductive elements. The first conductive element can have multiple electrical contacts, of identical or different configurations, or may be in the form of a conductive pad, and can contact or otherwise electrically interconnect with the substrate surface over substantially all of the substrate surface. Upon application of a potential between the first and second conductive elements while the electrolyte makes physical contact with the substrate surface and the second conductive element, the conductive material is deposited on the substrate surface. It is possible to reverse the polarity of the voltage applied between the anode and the cathode so that electro-etching of deposited conductive material can be performed.

Abstract: Systems and methods to remove a first material located on a top surface of a workpiece are presented according to one aspect of the present invention. According to an exemplary method, the pad including a second material is positioned proximate to the workpiece so that a front surface of the pad contacts an exposed surface of the first material. The front surface of the pad is mechanically moved against the exposed surface of the first material to initiate a chemical reaction between the first material and the second material that yields a reaction product. The reaction product may be removed by using a chemical solution, by using the mechanical movement of the pad against the exposed surface of the first material or both.

Abstract: Substantially uniform deposition of conductive material on a surface of a substrate, which substrate includes a semiconductor wafer, from an electrolyte containing the conductive material can be provided by way of a particular device which includes first and second conductive elements. The first conductive element can have multiple electrical contacts, of identical or different configurations, or may be in the form of a conductive pad, and can contact or otherwise electrically interconnect with the substrate surface over substantially all of the substrate surface. Upon application of a potential between the first and second conductive elements while the electrolyte makes physical contact with the substrate surface and the second conductive element, the conductive material is deposited on the substrate surface. It is possible to reverse the polarity of the voltage applied between the anode and the cathode so that electro-etching of deposited conductive material can be performed.

Abstract: A system for depositing materials on a surface of a wafer includes an anode, a shaping plate, a liquid electrolyte contained between the anode and the surface of the wafer, and electrical contact members contacting selected locations on the surface of the wafer. The shaping plate defines a recessed edge and is supported between the anode and the surface of the wafer such that an upper surface of the shaping plate faces the surface of the substrate. The shaping plate can have a plurality of channels such that each puts the surface of the wafer in a fluid communication with the anode. The deposition process progresses through the shaping plate. The upper surface of the shaping plate has a substantially larger area than the area of the surface of the wafer.

Abstract: Substantially uniform deposition of conductive material on a surface of a substrate, which substrate includes a semiconductor wafer, from an electrolyte containing the conductive material can be provided by way of a particular device which includes first and second conductive elements. The first conductive element can have multiple electrical contacts, of identical or different configurations, or may be in the form of a conductive pad, and can contact or otherwise electrically interconnect with the substrate surface over substantially all of the substrate surface. Upon application of a potential between the first and second conductive elements while the electrolyte makes physical contact with the substrate surface and the second conductive element, the conductive material is deposited on the substrate surface. It is possible to reverse the polarity of the voltage applied between the anode and the cathode so that electro-etching of deposited conductive material can be performed.

Abstract: The present invention relates to methods and apparatus for plating a conductive material on a semiconductor substrate by rotating pad or blade type objects in close proximity to the substrate, thereby eliminating/reducing dishing and voids. This is achieved by providing pad or blade type objects mounted on cylindrical anodes or rollers and applying the conductive material to the substrate using the electrolyte solution disposed on or through the pads, or on the blades. In one embodiment of the invention, the pad or blade type objects are mounted on the cylindrical anodes and rotated about a first axis while the workpiece may be stationary or rotate about a second axis, and metal from the electrolyte solution is deposited on the workpiece when a potential difference is applied between the workpiece and the anode. In another embodiment of the present invention, the plating apparatus includes an anode plate spaced apart from the cathode workpiece.

Abstract: The present invention applies an electrochemical etching solution to a material layer, preferably a metal layer, disposed on a workpiece, in the presence of a current. This electrochemical etching solution supplies to the material on the substrate surface the species to form an intermediate compound on the surface that can be more easily mechanically removed as intermediate compound fragments than the material. By removing the intermediate compound fragments, the process allows more efficient use of the supplied current to form another layer of intermediate compound that can also be mechanically removed, rather than using the current to result in another compound on the surface of the material that eventually dissolves into the solution. In another aspect of the invention, such intermediate compound particulates are externally generated and used to mechanically remove the surface layer of the material.

Abstract: An integrated process tool for chemical mechanical processing, cleaning and drying a semiconductor workpiece is provided. The integrated process tool includes a CMP module and a cleaning and drying module. After being processed, the workpiece is transported from the CMP module to the cleaning and drying module using a movable housing. In the cleaning and drying module, a cleaning mechanism is used to clean the workpiece while the workpiece is rotated and held by a support stucture of the movable housing. A drying mechanism of the cleaning and drying module picks up the workpiece from the moveable housing and spin dries it. Throughout the CMP process, cleaning and drying, the processed surface of the wafer faces down.

Abstract: The present invention relates to a method for fabricating high performance chip interconnects and packages by providing methods for depositing a conductive material in cavities of a substrate in a more efficient and time saving manner. This is accomplished by selectively removing portions of a seed layer from a top surface of a substrate and then depositing a conductive material in the cavities of the substrate, where portions of the seed layer remains in the cavities. Another method includes forming an oxide layer on the top surface of the substrate such that the conductive material can be deposited in the cavities without the material being formed on the top surface of the substrate. The present invention also discloses methods for forming multi-level interconnects and the corresponding structures.

Abstract: A method for forming conductor structures on a semiconductor wafer is provided. The method begins with depositing a seed layer having a substantially consistent thickness over a barrier layer that covers the features and the field regions among them. The process continues with electrodepositing a planar copper layer on the seed layer and subsequently electroetching it until a thinned seed layer remains over the field regions. When another layer of planar copper is deposited on the remaining copper in the features and on the thinned seed layer on the field regions, this structure minimizes stress related defects in the features which occur during a following anneal process.

Abstract: A system for depositing materials on a surface of a wafer or removing materials from the surface of a wafer includes an electrode, a shaping plate, a liquid solution contained between the electrode and the wafer surface, and electrical contact members contacting selected locations on the wafer surface. The shaping plate is supported between the electrode and the wafer surface such that an upper surface of the shaping plate faces the wafer surface. The shaping plate can have a plurality of channels where each puts the wafer surface in a fluid communication with the electrode. The electrical contact members contact the selected locations on the wafer surface through a recessed edge of the shaping plate such that when the wafer is rotated, the selected contact locations move over the shaping plate and are plated under an applied potential. Advantages of the invention include substantially full surface treatment of the wafer.

Abstract: The methods and systems described provide for an in-situ endpoint detection for material removal processes such as chemical mechanical polishing (CMP) performed on a workpiece. In a preferred embodiment, an optical detection system is used to detect endpoint during the removal of planar conductive layers using CMP. An optically transparent polishing belt provides endpoint detection through any spot on the polishing belt. Once endpoint is detected, a signal can be used to terminate or alter a CMP process that has been previously initiated.

Abstract: The present invention includes a polishing pad or belt secured to a mechanism that allows the pad or belt to move in a reciprocating manner, i.e. in both forward and reverse directions, at high speeds. The constant bidirectional movement of the polishing pad or belt as it polishes the wafer provides superior planarity and uniformity across the wafer surface. When a fresh portion of the pad is required, the pad is moved through a drive system containing rollers, such that the rollers only touch a back side of the pad, thereby minimizing sources of friction other than the wafer that is being polished from the polishing side of the pad, and maximizing the lifetime of the polishing pad.

Abstract: Systems and methods to operate upon a nonplanar top surface of a conductive surface layer of a workpiece, so as to, for example, preserve the structural integrity of a dielectric film layer disposed below the conductive surface layer, are presented. According to an exemplary method, a layer of conducting material such as a conducting paste is applied over the nonplanar top surface of the conductive surface layer to obtain a planar top surface. At least a portion of the conducting material layer and at least a portion of the conductive surface layer are removed in a planar manner to at least partially planarize the nonplanar top surface. The conducting material layer may be annealed so that the conducting material layer diffuses with the conductive surface layer prior to removal of at least the portions of conducting material layer and the conductive surface layer.

Abstract: The present invention relates to a process for forming a near-planar or planar layer of a conducting material, such as copper, on a surface of a workpiece using an ECMPR technique. The process preferably uses at least two separate plating solution chemistries to form a near-planar or planar copper layer on a semiconductor substrate that has features or cavities on its surface.

Abstract: The present invention provides an apparatus for electrochemical mechanical processing of a surface of a workpiece by utilizing a process solution. The apparatus of the present invention includes an electrode touching the process solution, a belt workpiece surface influencing device extended between a supply spool and a receiving spool. During the process, the surface of the workpiece is placed in proximity of the workpiece surface influencing device and the process solution is flowed through the process section and onto the surface while a potential difference is applied between the electrode and the surface of the workpiece.

Abstract: The present invention deposits a conductive material from an electrolyte solution to a predetermined area of a wafer. The steps that are used when making this application include applying the conductive material to the predetermined area of the wafer using an electrolyte solution disposed on a surface of the wafer, when the wafer is disposed between a cathode and an anode, and preventing accumulation of the conductive material to areas other than the predetermine area by mechanically polishing the other areas while the conductive material is being applied.

Abstract: The present invention includes a polishing pad or belt secured to a mechanism that allows the pad or belt to move in a reciprocating manner, i.e. in both forward and reverse directions, at high speeds. The constant bidirectional movement of the polishing pad or belt as it polishes the wafer provides superior planarity and uniformity across the wafer surface. When a fresh portion of the pad is required, the pad is moved through a drive system containing rollers, such that the rollers only touch a back side of the pad, thereby minimizing sources of friction other than the wafer that is being polished from the polishing side of the pad, and maximizing the lifetime of the polishing pad.

Abstract: Systems and methods to provide electrical contacts to a workpiece to facilitate electrotreating processes, including electroplating and electroetching processes are presented.

Abstract: Systems and methods to provide electrical contacts to a workpiece to facilitate electrotreating processes, including electroplating and electroetching processes are presented.