Abstract: An ion implantation apparatus, system, and method are provided for connecting and disconnecting a workpiece holder from a scan arm. A twist head is provided, wherein an electrostatic chuck is operable to be mounted, wherein one or more rotating and non-rotating members associated with one or more of the twist head and electrostatic chuck have one or more dynamic electrical and fluid rotary connections associated therewith. The electrostatic chuck is further operable to be removed from the twist head without disconnecting the one or more dynamic fluid seals.

Abstract: A combination load lock apparatus is provided, wherein a chamber is coupled to two or more valves in selective fluid communication with two or more respective volumes. A support member for supporting a workpiece is disposed within an interior portion of the chamber, wherein a translation apparatus is operably coupled thereto. The translation apparatus is operable to rotate and/or translate the workpiece on the support member about and/or along a first axis, wherein a detection apparatus associated with the chamber is operable to detect one or more characteristics of the workpiece during the rotation and/or translation thereof. The workpiece may be further rotated in a predetermined manner based on the one or more detected characteristics. A recess is further defined in the interior portion of the chamber, wherein the translation apparatus is operable to translate the workpiece into and out of the recess to reduce particulate contamination thereon.

Abstract: An electrostatic clamp for securing a semiconductor wafer during processing. The electrostatic clamp includes a base member, a first dielectric layer, a second dielectric layer having a gas pressure distribution micro-groove network formed therein, a gas gap positioned between a backside of a semiconductor wafer and the second dielectric layer, and a pair of high voltage electrodes positioned between the first dielectric layer and the second dielectric layer.

Abstract: A vertical rapid thermal processing system includes a processing chamber and an elevator structure providing for vertical movement of a workpiece within the processing chamber. The elevator structure includes a workpiece support for supporting the workpiece and an elevator shaft coupled to the workpiece support and extending externally from the processing chamber. An end portion of the elevator shaft, external to the processing chamber, has a selected magnetic polarity. The elevator structure also includes moveable carriage coupled to the shaft to provide vertical movement of the workpiece within the processing chamber. The carriage includes a shaft support having the selected polarity. The shaft support is positioned adjacent the polarized end portion of the elevator shaft such that repulsive magnetic forces maintain a gap between the end portion of the elevator shaft and the shaft support as the shaft support and elevator shaft move vertically along a path of travel.

Abstract: A workpiece is supported on a gas cushion to reduce mechanical stresses on the workpiece during processing. A plenum having a workpiece support flange for receiving the workpiece is connected to a gas supply. When gas flows into the plenum and pressure increases sufficiently to lift the workpiece, the workpiece is lifted and the gas flows out of the plenum between the flange and the workpiece edge. The workpiece is thus supported above the flange by the gas during processing.

Abstract: A wafer support position control mechanism selectively positions a semiconductor wafer along an axis of excursion within a process chamber. An elevator tube protrudes through an orifice in the chamber surface and is connected at a first distal end to the wafer support. A compliant, dynamic seal within the orifice engages the elevator tube to form a gas curtain within a gap between the seal and the elevator tube to seal the process chamber. A moveable carriage is connected to the elevator tube at a second distal end for moving the wafer support along the axis of excursion. Rigid mechanical structure couples the second distal end of the elevator tube to the moveable carriage.

Abstract: A vertical rapid thermal processing system includes a processing chamber and an elevator structure providing for vertical movement of a workpiece within the processing chamber. The elevator structure includes a workpiece support for supporting the workpiece and an elevator shaft coupled to the workpiece support and extending externally from the processing chamber. An end portion of the elevator shaft, external to the processing chamber, has a selected magnetic polarity. The elevator structure also includes moveable carriage coupled to the shaft to provide vertical movement of the workpiece within the processing chamber. The carriage includes a shaft support having the selected polarity. The shaft support is positioned adjacent the polarized end portion of the elevator shaft such that repulsive magnetic forces maintain a gap between the end portion of the elevator shaft and the shaft support as the shaft support and elevator shaft move vertically along a path of travel.

Abstract: An end effector for installation on a robotic arm for transporting a plurality of semiconductor wafers from one location to another features a ceramic end effector body portion that includes a plurality of wafer engaging fingers that each feature wafer support pads. The wafer support pads are adapted to support a semiconductor wafer surface, and at least one of the support pads has a vacuum orifice. The pads are replaceable and/or removable in case of damage or contamination. The support pads are attached to the body in such a way as to allow differential thermal expansion so as to prevent introduction of stress into the components. Typically, a wire spring is employed to secure the pad to the end effector. The body portion features an interior vacuum passageway having a first end that is adapted to connect to a vacuum source and a second end that terminates at the vacuum orifices such that a reduced gas pressure at the first end causes a vacuum to be exerted at the vacuum orifices.

Abstract: A wafer support position control mechanism selectively positions a semiconductor wafer along an axis of excursion within a process chamber. An elevator tube protrudes through an orifice in the chamber surface and is connected at a first distal end to the wafer support. A compliant, dynamic seal within the orifice engages the elevator tube to form a gas curtain within a gap between the seal and the elevator tube to seal the process chamber. A moveable carriage is connected to the elevator tube at a second distal end for moving the wafer support along the axis of excursion. Rigid mechanical structure couples the second distal end of the elevator tube to the moveable carriage.

Abstract: A workpiece is supported on a gas cushion to reduce mechanical stresses on the workpiece during processing. A plenum having a workpiece support flange for receiving the workpiece is connected to a gas supply. When gas flows into the plenum and pressure increases sufficiently to lift the workpiece, the workpiece is lifted and the gas flows out of the plenum between the flange and the workpiece edge. The workpiece is thus supported above the flange by the gas during processing.

Abstract: An electrostatic clamp for securing a semiconductor wafer during processing. The electrostatic clamp comprises a base member, a resistive layer, a dielectric layer including a gas pressure distribution micro-groove network, a gas gap positioned between a backside of a semiconductor wafer and the dielectric layer, and a pair of high voltage electrodes positioned between the resistive layer and the dielectric layer. The electrostatic clamp can further comprise at least one ground electrode positioned between the resistive layer and the dielectric layer that provides shielding for the gas pressure distribution micro-groove network. The electrostatic clamp is characterized by a heat transfer coefficient of greater than or about 200 mW/Kcm2, a response time of less than or about 1 second, and gas leakage of less than or about 0.5 sccm.

Abstract: An end effector for installation on a robotic arm for transporting a plurality of semiconductor wafers from one location to another features a ceramic end effector body portion that includes a plurality of wafer engaging fingers that each feature wafer support pads. The wafer support pads are adapted to support a semiconductor wafer surface, and at least one of the support pads has a vacuum orifice. The body portion features an interior vacuum passageway having a first end that is adapted to connect to a vacuum source and a second end that terminates at the vacuum orifices such that a reduced gas pressure at the first end causes a vacuum to be exerted at the vacuum orifices. The interior passageway is formed from a groove in the end effector body portion and an end effector backplate that is sealingly connected to the end effector body portion to completely cover the groove from the first end to the second end. The ceramic body portion can be made of alumina or silicon carbide.

Abstract: The invention provides a wafer pad assembly and actuation system for use in an ion implanter, preferably a batch-type ion implanter. The wafer pad assembly includes a rotatable wafer support pad having an upper surface for mounting the wafer, and a lower surface rotationally mounted to a housing of the wafer pad assembly. The lower surface of the wafer support pad further comprises a flange connected to a rotatable shaft. The shaft is connected to an actuator for selectively indexing the shaft so that the wafer support pad is rotationally indexed about its geometric center. The lower surface of the wafer support pad is also connected to a frame having an outer curved surface rotatably mounted within a mating bearing surface of a housing. The curved frame is connected to a plurality of linkages for moving the wafer support pad within the curved frame so that the wafer is pivotable or tiltable about its geometric center.

Abstract: The invention provides a wafer pad assembly and actuation system for use in an ion implanter, preferably a batch-type ion implanter. The wafer pad assembly includes a rotatable wafer support pad having an upper surface for mounting the wafer, and a lower surface rotationally mounted to a housing of the wafer pad assembly. The lower surface of the wafer support pad further comprises a flange connected to a rotatable shaft. The shaft is connected to an actuator for selectively indexing the shaft so that the wafer support pad is rotationally indexed about its geometric center. The lower surface of the wafer support pad is also connected to a frame having an outer curved surface rotatably mounted within a mating bearing surface of a housing. The curved frame is connected to a plurality of linkages for moving the wafer support pad within the curved frame so that the wafer is pivotable or tiltable about its geometric center.

Abstract: A charge neutralization monitor monitors the operation of a charge neutralization system for an ion implantation system. The charge neutralization system produces neutralizing electrons in a region through which an ion beam passes in treating one or more workpieces. The charge neutralization monitor applies a suitable voltage to a target electrode positioned to collect neutralizing electrons produced by the charge neutralization system. The charge neutralization monitor then determines the available neutralizing electron current that may be produced by the charge neutralization system by monitoring the current flowing through the target electrode.