Abstract: A voltage supply incorporates two voltage supplies connected in a mirror-image series arrangement to generate a DC voltage between the respective common terminals of the voltage supplies.

Abstract: A method and apparatus for processing a substrate utilizing a rotating substrate support are disclosed herein. In one embodiment, an apparatus for processing a substrate includes a chamber having a substrate support assembly disposed within the chamber. The substrate support assembly includes a substrate support having a support surface and a heater disposed beneath the support surface. A shaft is coupled to the substrate support and a motor is coupled to the shaft through a rotor to provide rotary movement to the substrate support. A seal block is disposed around the rotor and forms a seal therewith. The seal block has at least one seal and at least one channel disposed along the interface between the seal block and the shaft. A port is coupled to each channel for connecting to a pump. A lift mechanism is coupled to the shaft for raising and lowering the substrate support.

Abstract: An ion beam angle calibration and emittance measurement system, comprising a plate comprising an elongated slit therein, wherein the elongated slit positioned at a rotation center of the plate and configured to allow a first beam portion to pass therethrough. A beam current detector located downstream of the plate, wherein the beam current detector comprises a slit therein configured to permit a second beam portion of the first beam portion to pass therethrough, wherein the beam current detector is configured to measure a first beam current associated with the first beam portion. A beam angle detector is located downstream of the beam current detector and configured to detect a second beam current associated with the second beam portion. The plate, the current beam detector and the beam angle detector are configured to collectively rotate about the rotation center of the plate.

Abstract: An ion implantation system configured to produce an ion beam is provided, wherein an end station has a robotic architecture having at least four degrees of freedom. An end effector operatively coupled to the robotic architecture selectively grips and translates a workpiece through the ion beam. The robotic architecture has a plurality of motors operatively coupled to the end station, each having a rotational shaft. At least a portion of each rotational shaft generally resides within the end station, and each of the plurality of motors has a linkage assembly respectively associated therewith, wherein each linkage assembly respectively has a crank arm and a strut. The crank arm of each linkage assembly is fixedly coupled to the respective rotational shaft, and the strut of each linkage assembly is pivotally coupled to the respective crank arm at a first joint, and pivotally coupled to the end effector at a second joint.

Abstract: A system and method for magnetically filtering an ion beam during an ion implantation into a workpiece is provided, wherein ions are emitted from an ion source and accelerated the ions away from the ion source to form an ion beam. The ion beam is mass analyzed by a mass analyzer, wherein ions are selected. The ion beam is then decelerated via a decelerator once the ion beam is mass-analyzed, and the ion beam is further magnetically filtered the ion beam downstream of the deceleration. The magnetic filtering is provided by a quadrapole magnetic energy filter, wherein a magnetic field is formed for intercepting the ions in the ion beam exiting the decelerator to selectively filter undesirable ions and fast neutrals.

Abstract: This invention relates to a method of measuring a property of an ion beam, for example an ion beam current profile or the emittance of an ion beam. A Faraday array comprising an array of ion beam current sensors is employed. The array can provide an ion beam current profile at the plane of the array. The Faraday array is also used in conjunction with an occluding element that may be moved through the ion beam upstream of the Faraday array, there obscuring varying portions of the ion beam from the Faraday array. Suitable manipulation of the signals from the Faraday allows the ion beam current profile to be determined for the plane of the occluding element, and also for the emittance of the ion beam at the plane of the occluding element to be determined.

Abstract: This invention relates to a method of measuring a property of an ion beam, for example an ion beam current profile or the emittance of an ion beam. A Faraday array comprising an array of ion beam current sensors is employed. The array can provide an ion beam current profile at the plane of the array. The Faraday array is also used in conjunction with an occluding element that may be moved through the ion beam upstream of the Faraday array, there obscuring varying portions of the ion beam from the Faraday array. Suitable manipulation of the signals from the Faraday allows the ion beam current profile to be determined for the plane of the occluding element, and also for the emittance of the ion beam at the plane of the occluding element to be determined.

Abstract: A mechanical scanner for ion implantation of a substrate, the mechanical scanner comprising a hexapod with a movable platform for holding the substrate, wherein the hexapod is arranged to have six degrees of freedom to allow the movable platform to be traversed relative to an ion beam along a predetermined path.

Abstract: This invention relates to an apparatus for scanning substrates through an ion beam in the process chamber of an ion implanter. The apparatus comprises a substrate carriage and reaction mass carriage movably mounted to a fixed base. The substrate carriage is adapted to support a substrate holder. Movement of the substrate carriage results in movement of the substrate holder, and substrate mounted therein, through the ion beam. The reaction mass carriage moves in the opposite direction to the substrate carriage to counter any reaction forces exerted on the fixed base as a result of acceleration of the substrate carriage.

Abstract: A method and apparatus for processing a substrate utilizing a rotating substrate support are disclosed herein. In one embodiment, an apparatus for processing a substrate includes a chamber having a substrate support assembly disposed within the chamber. The substrate support assembly includes a substrate support having a support surface and a heater disposed beneath the support surface. A shaft is coupled to the substrate support and a motor is coupled to the shaft through a rotor to provide rotary movement to the substrate support. A seal block is disposed around the rotor and forms a seal therewith. The seal block has at least one seal and at least one channel disposed along the interface between the seal block and the shaft. A port is coupled to each channel for connecting to a pump. A lift mechanism is coupled to the shaft for raising and lowering the substrate support.

Abstract: This invention relates to an ion beam monitoring arrangement for use in an ion implanter where it is desirable to monitor the flux and/or a cross-sectional profile of the ion beam used for implantation. It is often desirable to measure the flux and/or cross-sectional profile of an ion beam in an ion implanter in order to improve control of ion implantation of a semiconductor wafer or similar. The present invention describes adapting the wafer holder to allow such beam profiling to be performed. The substrate holder may be used progressively to occlude the ion beam from a downstream flux monitor or a flux monitor may be located on the wafer holder that is provided with a slit entrance aperture.