Abstract: The present invention provides a wafer carrier that includes an opening, which in one embodiment is a plurality of holes, disposed along the periphery of the wafer carrier. A gas emitted through the holes onto a peripheral back edge of the wafer assists in preventing the processing liquids and contaminants resulting therefrom from reaching the inner region of the base and the backside inner region of the wafer. In another embodiment, a plurality of concentric sealing members are used to prove a better seal, and the outer seal is preferably independently movable to allow cleaning of a peripheral backside of the wafer to occur while the wafer is still attached to the wafer carrier.

Abstract: Conductive structures in features of an insulator layer on a substrate are fabricated by a particular process. In this process, a layer of conductive material is applied over the insulator layer so that the layer of conductive material covers field regions adjacent the features and fills in the features themselves. A grain size differential between the conductive material which covers the field regions and the conductive material which fills in the features is then established by annealing the layer of conductive material. Excess conductive material is then removed to uncover the field regions and leave the conductive structures. The layer of conductive material is applied so as to define a first layer thickness over the field regions and a second layer thickness in and over the features. These thicknesses are dimensioned such that d1?0.5d2, with d1 being the first layer thickness and d2 being the second layer thickness. Preferably, the first and second layer thicknesses are dimensioned such that d1?0.3d2.

Abstract: The present invention relates to a containment chamber that is used for carrying out multiple processing steps such as depositing on, polishing, etching, modifying, rinsing, cleaning, and drying a surface on the workpiece. In one example of the present invention, the chamber is used to electro chemically mechanically deposit a conductive material on a semiconductor wafer. The same containment chamber can then be used to rinse and clean the same wafer. As a result, the present invention eliminates the need for separate processing stations for depositing the conductive material and cleaning the wafer. Thus, with the present invention, costs and physical space are reduced while providing an efficient apparatus and method for carrying out multiple processes on the wafer surface using a containment chamber.

Abstract: In one aspect, the present invention monitors a signal corresponding to a torque value of a motor that is used to maintain relative motion between a conductive top surface of a workpiece and a workpiece surface influencing device in the presence of physical contact between the conductive top surface of the workpiece and the workpiece surface influencing device. In another aspect, the present invention uses the signal to control a force applied to a top conductive surface of a workpiece during electrotreatment.

Abstract: The present invention is directed to a method and apparatus for plating a surface of a semiconductor workpiece (wafer, flat panel, magnetic films, etc.) using a liquid conductor that makes contact with the outer surface of the workpiece. The liquid conductor is stored in a reservoir and pump through an inlet channel to the liquid chamber. The liquid conductor is injected into a liquid chamber such that the liquid conductor makes contact with the outer surface of the workpiece. An inflatable tube is also provided to prevent the liquid conductor from reaching the back face of the workpiece. A plating solution can be applied to the front face of the workpiece where a retaining ring/seal further prevents the plating solution and the liquid conductor from making contact with each other. In an alternative embodiment, electrical contacts may be formed using an inflatable tube that has either been coated with a conductive material or contains a conductive object.

Abstract: An integrated system for processing a plurality of wafers, having a conductive front surface, is provided. The system includes a plurality of processing subsystems for depositing on or removing metal from the front surfaces of the wafers. Each processing subsystem includes a process chamber and a cleaning chamber. The system also has a wafer handling subsystem for transporting each of the wafers into or out of the appropriate one of the plurality of processing subsystems. The plurality of processing subsystems and wafer handling subsystem form an integrated system.

Abstract: The present invention relates to a method for forming a planar conductive surface on a wafer. In one aspect, the present invention uses a no-contact process with electrochemical deposition, followed by a contact process with electrochemical mechanical deposition.

Abstract: The process of the present invention forms copper interconnects in a semiconductor wafer surface. During the process, initially, narrow and large features are provided in the top surface of the wafer, and then a primary copper layer is deposited by employing an electrochemical deposition process. The primary copper layer completely fills the features and forms a planar surface over the narrow feature and a non-planar surface over the large feature. By employing an electrochemical mechanical deposition process, a secondary copper layer is deposited onto the primary copper layer to form a planar copper layer over the narrow and large features. After this process step, the thickness of the planar copper layer is reduced using an electropolishing process.

Abstract: An apparatus for processing a material on a wafer surface includes a cavity defined by a peripheral wall and configured to direct a process solution and direct it to the surface to to a first wafer surface region without being directed to a second wafer surface region, a head configured to hold the wafer so that the surface of the wafer faces the cavity, and an electrical contact member positioned outside the cavity peripheral wall and configured to contact the second wafer surface region extending beyond the cavity, when the wafer is moved relative to the contact member. Advantages of the invention include substantially full surface treatment of the wafer.

Abstract: A sensing apparatus for detecting a processing endpoint of a multi-layer semiconductor wafer includes a light source to emit light against a surface of the semiconductor wafer, a color sensor to sense a reflection color from the surface of the semiconductor wafer in response to the incident light and to generate a sensor signal, and a decision circuit coupled to the color sensor and configured to decide whether the wafer processing endpoint has been reached based at least in part on the sensor signal. In another embodiment, a sensing apparatus is coupled to a movable structure to position the sensing apparatus to sense the surface of the semiconductor wafer.

Abstract: The present invention provides a wafer carrier that includes a plurality of concentric sealing members that provide a seal, with the outer seal independently movable to allow cleaning of a peripheral backside of the wafer to occur while the wafer is still attached to the wafer carrier, and a plurality of vacuum openings that a re disposed only adjacent to an inner side of the inner seal at a location corresponding to the backside periphery of the wafer.

Abstract: A fluid bearing polishing apparatus for carrying a polishing member for chemical mechanical polishing includes a fluid supply and a fluid dispensing structure to support the polishing member. A method of polishing a workpiece includes supporting a polishing member on a fluid bearing between a first end of the polishing member and a second end of the polishing member and moving the polishing member to polish the workpiece. The fluid bearing has a curved portion at which plane of travel of the polishing member changes from a first plane to a second plane. Advantages of the invention include smooth belt motion in all desired directions of movement.

Abstract: The methods and systems described provide for an in-situ detection of planarity of a layer that is deposited on or etched off the surface of a substrate. Planarity can be detected using various detection mechanisms, including optical, electrical, mechanical and acoustical, in combination with the electrochemical mechanical processing methods, including electrochemical mechanical deposition and electrochemical mechanical etching. Once planarity is detected, a planarity signal can be used to terminate or alter a process that has been previously initiated, or begin a new process. In a preferred embodiment, an optical detection system is used to detect planarity during the formation of planar conductive layers obtained by electrochemical mechanical processing.

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: The present invention relates to methods and apparatus that allow for chemical mechanical polishing using a flexible pad and variable fluid flow for variable polishing.

Abstract: The present invention relates to methods and apparatus for plating a conductive material on a workpiece surface in a highly desirable manner. Using a workpiece-surface-influencing device, such as a mask or sweeper, that preferentially contacts the top surface of the workpiece, relative movement between the workpiece and the workpiece-surface-influencing device is established so that an additive in the electrolyte solution disposed on the workpiece and which is adsorbed onto the top surface is removed or otherwise its amount or concentration changed with respect to the additive on the cavity surface of the workpiece. Plating of the conductive material can place prior to, during and after usage of the workpiece-surface-influencing device, particularly after the workpiece surface influencing device no longer contacts any portion of the top surface of the workpiece, to achieve desirable semiconductor structures.

Abstract: The present invention describes a chemical mechanical polishing apparatus and method that uses a portion of a polishing pad that is disposed under tension between a supply spool and a receive spool, with a motor providing the tension to either the supply spool or the receive spool and the other spool being locked during processing. If a new section of the polishing pad is needed, the same motor that provided the tension is used to advance the polishing pad a determined amount. Further, during processing, a feedback mechanism is used to ensure that the tension of the polishing pad is consistently maintained.

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: 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 relates to a containment chamber that is used for carrying out multiple processing steps such as depositing on, polishing, etching, modifying, rinsing, cleaning, and drying a surface on the workpiece. In one example of the present invention, the chamber is used to electro chemically mechanically deposit a conductive material on a semiconductor wafer. The same containment chamber can then be used to rinse and clean the same wafer. As a result, the present invention eliminates the need for separate processing stations for depositing the conductive material and cleaning the wafer. Thus, with the present invention, costs and physical space are reduced while providing an efficient apparatus and method for carrying out multiple processes on the wafer surface using a containment chamber.