Abstract: A method and apparatus for temperature control for a chemical mechanical polishing process is provided. In one embodiment, the method comprises polishing the substrate with a surface of a polishing pad assembly, measuring a real-time temperature of the surface of the polishing pad assembly, determining whether the real-time temperature of the surface of the polishing pad assembly is within a predetermined processing temperature range, and contacting the surface of the polishing pad assembly with a pad conditioner to adjust the temperature of the surface of the polishing pad assembly to fall within the predetermined temperature range.

Abstract: A difference between a first expected required polish time for a first substrate and a second expected required polish time for a second substrate is determined using a first pre-polish thickness and a second pre-polish thickness measured at an in-line metrology station. A duration of an initial period is determined based on the difference between the first expected required polish time and the second expected required polish time. For the initial period at a beginning of a polishing operation, no pressure is applied to whichever of the first substrate and the second substrate has a lesser expected required polish time while simultaneously pressure is applied to whichever of the first substrate and the second substrate has a greater expected required polish time. After the initial period, pressure is applied to both the first substrate and the second substrate.

Abstract: An apparatus and method for simulating a substrate being polished in a multiple carrier head per platen station when no substrate is provided in one or more of the multiple carrier heads is described. In one embodiment, a method for processing a substrate includes providing a single substrate to a polishing station adapted to process a plurality of substrates on a single polishing pad using at least a first carrier head and a second carrier head, retaining the single substrate in the first carrier head while the second carrier head remains substrate-free, urging the first carrier head and the second carrier head toward a polishing surface of the polishing pad; and providing relative movement between the polishing pad and the first carrier head.

Abstract: A polishing method includes simultaneously polishing two substrates, a first substrate and a second substrate, on the same polishing pad. A default overpolishing time is stored and an in-situ monitoring system monitors the two substrates. The in-situ monitoring system further determines a first polishing endpoint time and a second polishing endpoint time of the first and second substrates, respectively. The polishing method further includes calculating an overpolishing stop time where the overpolishing stop time is between the first polishing endpoint time plus the default overpolishing time and the second polishing endpoint time plus the default overpolishing time. Polishing of the first substrate is continued past the first polishing endpoint time and polishing of the second substrate is continued past the second polishing endpoint time. Polishing of both the first substrate and the second substrate is halted simultaneously at the overpolishing stop time.

Abstract: Embodiments of the present invention generally relate to a substrate transferring system. One embodiment of the present invention provides a substrate holder comprising a pedestal plate, a basin wall extending from a top surface of the pedestal plate, wherein the basin wall has a substantially leveled top surface, the basin wall and the pedestal plate define a basin configured to retain a liquid therein, and a liquid port opening to the basin, wherein the liquid port is configured to flow a liquid to the basin and allow the liquid to overflow from the basin wall, and a top surface of the overflow liquid in the basin is configured to support a substrate without contacting the basin wall or the pedestal plate.

Abstract: A chemical mechanical polishing apparatus including a platen for holding a pad having a polishing surface, a subsystem for holding a substrate and the polishing surface together during a polishing step, and a temperature sensor oriented to measure a temperature of the polishing surface, wherein the subsystem accepts the temperature measured by the sensor and is programmed to vary a polishing process parameter in response to the measured temperature. In an aspect, a chemical mechanical polishing apparatus having a platen for holding a pad having a polishing surface, a fluid delivery system for transporting a fluid from a source to the polishing surface, and a temperature controller which during operation controls the temperature of the fluid transported by the delivery system.

Abstract: A computer-implemented method includes polishing substrates simultaneously in a polishing apparatus. Each substrate has a polishing rate independently controllable by an independently variable polishing parameter. Measurement data that varies with the thickness of each of the substrates is acquired from each of the substrates during polishing with an in-situ monitoring system. A projected thickness that each substrate will have at a target time is determined based on the measurement data. The polishing parameter for at least one substrate is adjusted to adjust the polishing rate of the at least one substrate such that the substrates have closer to the same thickness at the target time than without the adjustment.

Abstract: A computer-implemented method includes polishing substrates simultaneously in a polishing apparatus. Each substrate has a polishing rate independently controllable by an independently variable polishing parameter. Measurement data that varies with the thickness of each of the substrates is acquired from each of the substrates during polishing with an in-situ monitoring system. A projected time at which each substrate will reach a target thickness is determined based on the measurement data. The polishing parameter for at least one substrate is adjusted to adjust the polishing rate of the at least one substrate such that the substrates reach the target thickness closer to the same time than without the adjustment.

Abstract: A method and apparatus for temperature control for a chemical mechanical polishing process is provided. In one embodiment, the method comprises polishing the substrate with a surface of a polishing pad assembly, measuring a real-time temperature of the surface of the polishing pad assembly, determining whether the real-time temperature of the surface of the polishing pad assembly is within a predetermined processing temperature range, and contacting the surface of the polishing pad assembly with a pad conditioner to adjust the temperature of the surface of the polishing pad assembly to fall within the predetermined temperature range.

Abstract: Embodiments of the present invention generally relate to a substrate transferring system. One embodiment of the present invention provides a substrate holder comprising a pedestal plate, a basin wall extending from a top surface of the pedestal plate, wherein the basin wall has a substantially leveled top surface, the basin wall and the pedestal plate define a basin configured to retain a liquid therein, and a liquid port opening to the basin, wherein the liquid port is configured to flow a liquid to the basin and allow the liquid to overflow from the basin wall, and a top surface of the overflow liquid in the basin is configured to support a substrate without contacting the basin wall or the pedestal plate.

Abstract: Embodiments described herein generally provide a method for processing metals disposed on a substrate in a chemical mechanical polishing system. The apparatus advantageously facilitates efficient bulk and residual conductive material removal from a substrate. In one embodiment a method for chemical mechanical polishing (CMP) of a conductive material disposed on a substrate is provided. A substrate comprising a conductive material disposed over an underlying barrier material is positioned on a first platen containing a first polishing pad. The substrate is polished on a first platen to remove a bulk portion of the conductive material. A rate quench process is performed in order to reduce a metal ion concentration in the polishing slurry. The substrate is polished on the first platen to breakthrough the conductive material exposing a portion of the underlying barrier material.

Abstract: A method and apparatus for pre-conditioning a new soft polishing pad and processing a substrate on a soft polishing pad is described. The method includes coupling a soft polishing pad to a platen, contacting the processing surface of the soft polishing pad with a conditioning disk, applying a pressure conditioning disk, removing the conditioning disk from contact with the processing surface of the soft polishing pad, and contacting a first substrate with the processing surface of the soft polishing pad to perform a polishing process on the first substrate.

Abstract: A belt wiper that can be used in a linear belt-type chemical mechanical planarization (CMP) system to maintain a belt pad is provided. The belt wiper mitigates disturbances within a detection region important to a belt pad steering system. Also, the belt wiper mitigates the obscuring of optical components important to operation of an endpoint detection system. Thus, the belt wiper, by wiping the underside of the belt pad will preserve the functionality of both the belt pad steering system and the endpoint detection system.

Abstract: A multi-step polishing system, and a process for polishing a workpiece using the system. The system includes one or more polishing stations. The workpiece is polished in the presence of an oxidizer-free medium, and subsequently, the workpiece is polished in the presence of an oxidizing medium. This polishing sequence extends the life of the polishing pads and provides for a more uniform polish.