Abstract: A method and apparatus for removing conductive material from a microelectronic substrate. In one embodiment, a support member supports a microelectronic substrate relative to first and second electrodes, which are spaced apart from each other and spaced apart from the microelectronic substrate. One or more electrolytes are disposed between the electrodes and the microelectronic substrate to electrically link the electrodes to the microelectronic substrate. The electrodes are then coupled to a source of varying current that electrically removes the conductive material from the substrate. The microelectronic substrate and/or the electrodes can be moved relative to each other to position the electrodes relative to a selected portion of the microelectronic substrate, and the electrodes can be integrated with a planarizing portion of the apparatus to remove material from the conductive layer by chemical-mechanical planarization.

Abstract: A chemical-mechanical polishing apparatus is provided with a downstream device for conditioning a web-shaped polishing pad. The device may be used to condition a glazed portion of the pad, and then the conditioned pad portion may be used again for polishing. The conditioning device is preferably arranged to apply different conditioning treatments to different portions of the glazed pad. The conditioning device may have roller segments that rotate at different speeds. Alternatively, the device may have non-cylindrical rollers that provide different rotational speeds at the pad surface, or the device may apply different pressures at different portions of the pad. The device may be arranged to provide uniform conditioning across the width of the pad. The invention is applicable to methods of planarizing semiconductor wafers. The invention may be used to condition circular pads in addition to web-shaped pads.

Abstract: An apparatus, program product and method improve management of available computing resources by adjusting use of the resource over a first interval according to actual use of the resource during a second interval. This feature enables a computing resource to exceed its normal limits during the first interval of operation. Use during the second interval may be limited to balance out the burst, or excessive resource usage of the first interval.

Abstract: Explosive forces are used to fill interconnect material into trenches, via holes and other openings in semiconductor products. The interconnect material may be formed of metal. The metal may be heated prior to the force filling step. The explosive forces may be generated, for example, by igniting mixtures of gases such as hydrogen and oxygen, or liquids such as alcohol and hydrogen peroxide. To control or buffer the explosive force, a baffle may be interposed between the explosions and the products being processed. The baffle may be formed of a porous material to transmit waves to the semiconductor products while protecting the products from contaminants. Various operating parameters, including the flow rate of the fuel and the oxidizing materials, may be positively controlled. In another embodiment of the invention, a piston is used to transmit the explosive force. If desired, an annular space at the periphery of the piston may be maintained at atmospheric pressure to protect against wafer contamination.

Abstract: Methods and devices for mechanical and/or chemical-mechanical planarization of semiconductor wafers, field emission displays and other microelectronic substrate assemblies. One method of planarizing a microelectronic substrate assembly in accordance with the invention includes pressing a substrate assembly against a planarizing surface of a polishing pad at a pad/substrate interface defined by a surface area of the substrate assembly contacting the planarizing surface. The method continues by moving the substrate assembly and/or the polishing pad with respect to the other to rub at least one of the substrate assembly and the planarizing surface against the other at a relative velocity. As the substrate assembly and polishing pad rub against each other, a parameter indicative of drag force between the substrate assembly and the polishing pad is measured or sensed at periodic intervals.

Abstract: A method and apparatus for cleaning a web-based chemical-mechanical planarization (CMP) system. Specifically, a fluid spray bar is coupled to a frame assembly which may be mounted on a CMP system. The fluid spray bar will move along the frame assembly. As the fluid spray bar traverses the length of the frame assembly, a cleaning fluid is sprayed onto the web in order to clean the web between planarization cycles.

Abstract: A method and apparatus autonomically analyze computer software performance to identify performance problems and isolate particular pieces of software that contribute to those performance problems to improve overall computer system performance. In preferred embodiments, performance problems are identified based on information learned from running an application, and instrumentation hooks are dynamically inserted at instrumentation points to isolate the performance problems.

Abstract: In one aspect, the invention includes a method of treating a surface of a substrate. A mixture which comprises at least a frozen first material and liquid second material is provided on the surface and moved relative to the substrate. In another aspect, the invention encompasses a method of treating a plurality of substrates. A treating member is provided proximate a first substrate, and an initial layer of frozen material is formed over a surface of the treating member. A surface of the first substrate is treated by moving at least one of the treating member and the first substrate relative to the other of the treating member and the first substrate. After the surface of the first substrate is treated, the initial layer of frozen material is removed from over the surface of the treating member.

Abstract: A method and apparatus for conditioning and monitoring a planarizing medium used for planarizing a microelectronic substrate. In one embodiment, the apparatus can include a conditioning body having a conditioning surface that engages a planarizing surface of the planarizing medium and is movable relative to the planarizing medium. A force sensor is coupled to the conditioning body to detect a frictional force imparted to the conditioning body by the planarizing medium when the conditioning body and the planarizing medium are moved relative to each other. The apparatus can further include a feedback device that controls the motion, position, or force between the conditioning body and the planarizing medium to control the conditioning of the planarizing medium.

Abstract: Methods and apparatus are disclosed for detecting solar cell defects by applying a forward-biasing electric current through a silicon solar cell or a group of interconnected solar cells for a short duration and then analyzing the resulting thermal image of each cell with an infrared (IR) camera. The invention is particularly useful in assembling solar cell arrays or modules in which large numbers of cells are to be wired together. Automated module assemblers are disclosed in which the cells (or strings of cells) are tested for defects prior to final module assembly.

Abstract: An apparatus, system and method for testing a peripheral device such that the device can remain installed in a housing and connected to a communication bus such as a SCSI bus. The apparatus, system, and method include a communication port that is connectable to a peripheral device connected to a terminated communication bus. The communication port is connected to a first transceiver and a second transceiver. A microcontroller is also connected to the first transceiver and the second transceiver. The microcontroller is programmed to detect an operation mode for the peripheral device and selectively activate the first transceiver or the second transceiver based on the detected operation mode. The microcontroller is further programmed to perform a logical diagnostic test on the peripheral device using the activated transceiver. A user interface is included to communicate to a user a result of the diagnostic test.

Abstract: Semiconductor processor systems, systems configured to provide a semiconductor workpiece process fluid, semiconductor workpiece processing methods, methods of preparing semiconductor workpiece process fluid, and methods of delivering semiconductor workpiece process fluid to a semiconductor processor are provided. One aspect of the invention provides a semiconductor processor system including a process chamber adapted to process at least one semiconductor workpiece using a process fluid; a connection coupled with the process chamber and configured to receive the process fluid; a sensor coupled with the connection and configured to output a signal indicative of the process fluid; and a control system coupled with the sensor and configured to control at least one operation of the semiconductor processor system responsive to the signal.

Abstract: Semiconductor processor systems, systems configured to provide a semiconductor workpiece process fluid, semiconductor workpiece processing methods, methods of preparing semiconductor workpiece process fluid, and methods of delivering semiconductor workpiece process fluid to a semiconductor processor are provided. One aspect of the invention provides a semiconductor processor system including a process chamber adapted to process at least one semiconductor workpiece using a process fluid; a connection coupled with the process chamber and configured to receive the process fluid; a sensor coupled with the connection and configured to output a signal indicative of the process fluid; and a control system coupled with the sensor and configured to control at least one operation of the semiconductor processor system responsive to the signal.

Abstract: An electroplating apparatus is provided with a metal target and a device for supporting a semiconductor wafer (or other workpiece) in an electroplating solution. The target (anode) may be located relatively far from the wafer surface (cathode) at the beginning of the plating process, until a sufficient amount of metal is plated. When an initial amount of metal is built up on the wafer surface, the target may be moved closer to the wafer for faster processing. The movement of the target may be controlled automatically according to one or more process parameters.

Abstract: An illumination system that has an output luminance (brightness) LO that is greater than the intrinsic output luminance (brightness) LI of the light emitting diodes used within the system. The system utilizes one or more light emitting diodes having highly reflective surfaces and recycles a portion of the light generated by the light emitting diodes back to the light emitting diodes in order to enhance the effective luminance. The illumination system includes a light-reflecting cavity and one or more highly reflective light emitting diodes having total surface area AS mounted inside the cavity, either on the interior surfaces of the cavity or within the cavity volume. The cavity has a light output aperture of area AO. The light emitting diodes have reflectivity RS. The exposed inside surfaces of the light-reflecting cavity have reflectivity RC. In order to achieve enhanced brightness, it is required that the area of the light output aperture AO be less than the total area AS of the light emitting diodes.

Abstract: A method and apparatus for removing conductive material from a microelectronic substrate is disclosed. One method includes disposing an electrolytic liquid between a conductive material of a substrate and at least one electrode, with the electrolytic liquid having about 80% water or less. The substrate can be contacted with a polishing pad material, and the conductive material can be electrically coupled to a source of varying electrical signals via the electrolytic liquid and the electrode. The method can further include applying a varying electrical signal to the conductive material, moving at least one of the polishing pad material and the substrate relative to the other, and removing at least a portion of the conductive material while the electrolytic liquid is adjacent to the conductive material. By limiting/controlling the amount of water in the electrolytic liquid, an embodiment of the method can remove the conductive material with a reduced downforce.

Abstract: A method and apparatus for removing conductive material from a microelectronic substrate is disclosed. One method includes disposing an electrolytic liquid between a conductive material of a substrate and at least one electrode, with the electrolytic liquid having about 80% water or less. The substrate can be contacted with a polishing pad material, and the conductive material can be electrically coupled to a source of varying electrical signals via the electrolytic liquid and the electrode. The method can further include applying a varying electrical signal to the conductive material, moving at least one of the polishing pad material and the substrate relative to the other, and removing at least a portion of the conductive material while the electrolytic liquid is adjacent to the conductive material. By limiting/controlling the amount of water in the electrolytic liquid, an embodiment of the method can remove the conductive material with a reduced downforce.

Abstract: Explosive forces are used to fill interconnect material into trenches, via holes and other openings in semiconductor products. The interconnect material may be formed of metal. The metal may be heated prior to the force filling step. The explosive forces may be generated, for example, by igniting mixtures of gases such as hydrogen and oxygen, or liquids such as alcohol and hydrogen peroxide. To control or buffer the explosive force, a baffle may be interposed between the explosions and the products being processed. The baffle may be formed of a porous material to transmit waves to the semiconductor products while protecting the products from contaminants. Various operating parameters, including the flow rate of the fuel and the oxidizing materials, may be positively controlled. In another embodiment of the invention, a piston is used to transmit the explosive force. If desired, an annular space at the periphery of the piston may be maintained at atmospheric pressure to protect against wafer contamination.

Abstract: A method and apparatus for removing conductive material from a microelectronic substrate. In one embodiment, a support member supports a microelectronic substrate relative to a material removal medium, which can include first and second electrodes and a polishing pad. One or more electrolytes are disposed between the electrodes and the microelectronic substrate to electrically link the electrodes to the microelectronic substrate. The electrodes are then coupled to a source of varying current that electrically removes the conductive material from the substrate. The microelectronic substrate and/or the electrodes can be moved relative to each other to position the electrodes relative to a selected portion of the microelectronic substrate, and/or to polish the microelectronic substrate. The material removal medium can remove gas formed during the process from the microelectronic substrate and/or the electrodes.

Abstract: A method and apparatus for removing conductive material from a microelectronic substrate. In one embodiment, a support member supports a microelectronic substrate relative to a material removal medium, which can include first and second electrodes and a polishing pad. One or more electrolytes are disposed between the electrodes and the microelectronic substrate to electrically link the electrodes to the microelectronic substrate. The electrodes are then coupled to a source of varying current that electrically removes the conductive material from the substrate. The microelectronic substrate and/or the electrodes can be moved relative to each other to position the electrodes relative to a selected portion of the microelectronic substrate, and/or to polish the microelectronic substrate. The material removal medium can remove gas formed during the process from the microelectronic substrate and/or the electrodes.