Abstract: A system and method for monitoring forces on a substrate lifting apparatus. The system includes a platen cartridge with a platen and a movable lifting portion. The movable lifting portion includes a plurality of lifting arms coupled to a plurality of lift pins. A plurality of force sensing elements are associated with respective ones of the plurality of lifting arms and the plurality of lift pins. A controller receives signals from the plurality of force sensing elements, correlates the signals to respective forces applied to said plurality of lift pins. The correlated forces may indicate to the controller that an error condition exists, such as a stuck wafer, a broken wafer, a mis-positioned wafer, or a mechanical malfunction.

Abstract: An improved method of producing solar cells utilizes a mask which is fixed relative to an ion beam in an ion implanter. The ion beam is directed through a plurality of apertures in the mask toward a substrate. The substrate is moved at different speeds such that the substrate is exposed to an ion dose rate when the substrate is moved at a first scan rate and to a second ion dose rate when the substrate is moved at a second scan rate. By modifying the scan rate, various dose rates may be implanted on the substrate at corresponding substrate locations. This allows ion implantation to be used to provide precise doping profiles advantageous for manufacturing solar cells.

Abstract: Techniques for manufacturing solar cells are disclosed. In one particular exemplary embodiment, the technique may be comprise disposing the solar cell downstream of an ion source; disposing a mask between the ion source and the solar cell, the mask including a front surface, a back surface, and at least one aperture extending in an aperture direction from the front surface to the back surface; and directing ions from the ion source to the solar cell along an ion beam path and through the at least one aperture of the mask, where the ion beam path may be non-parallel relative to the aperture direction.

Abstract: Various masks for use with ion implantation equipment are disclosed. In one embodiment, the masks are formed by assembling a collection of segments and spacers to create a mask having the desired configuration. This collection of parts is held together with a carrier or frame. In another embodiment, a panel is formed by machining open-ended slots into a substrate, so as to form a comb-shaped device. Two such panels may be connected together to form a mask. In other embodiments, the panels may be used sequentially in an ion implantation process to create interdigitated back contacts. In another embodiment, multiple masks are overlaid so as to create implant patterns that cannot be created effectively using a single mask.

Abstract: Techniques for changing temperature of a platen are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for changing temperature of a platen comprising a platen and one or more movable thermal pads comprising one or more thermal fluid channels to carry a thermal fluid configured to affect a temperature of the platen.

Abstract: A workpiece support is disclosed in which the platen, and thus the workpiece, can be tilted about at least two axis, which allows gravity to align the workpiece with a shadow mask in two orthogonal directions. In some embodiments, the workpiece support utilizes an axis of rotation that is orthogonal to the surface of the workpiece, in conjunction with a second axis that is parallel to the surface of the workpiece. Additionally, a method of aligning the workpiece using this workpiece support is also disclosed. Further, the workpiece support can be utilized to remove the workpiece from the support after implantation is completed.

Abstract: An improved method of producing solar cells utilizes a mask which is fixed relative to an ion beam in an ion implanter. The ion beam is directed through a plurality of apertures in the mask toward a substrate. The substrate is moved at different speeds such that the substrate is exposed to an ion dose rate when the substrate is moved at a first scan rate and to a second ion dose rate when the substrate is moved at a second scan rate. By modifying the scan rate, various dose rates may be implanted on the substrate at corresponding substrate locations. This allows ion implantation to be used to provide precise doping profiles advantageous for manufacturing solar cells.

Abstract: An improved method of producing solar cells utilizes a mask which is fixed relative to an ion beam in an ion implanter. The ion beam is directed through a plurality of apertures in the mask toward a substrate. The substrate is moved at different speeds such that the substrate is exposed to an ion dose rate when the substrate is moved at a first scan rate and to a second ion dose rate when the substrate is moved at a second scan rate. By modifying the scan rate, various dose rates may be implanted on the substrate at corresponding substrate locations. This allows ion implantation to be used to provide precise doping profiles advantageous for manufacturing solar cells.

Abstract: An improved method of producing solar cells utilizes a mask which is fixed relative to an ion beam in an ion implanter. The ion beam is directed through a plurality of apertures in the mask toward a substrate. The substrate is moved at different speeds such that the substrate is exposed to an ion dose rate when the substrate is moved at a first scan rate and to a second ion dose rate when the substrate is moved at a second scan rate. By modifying the scan rate, various dose rates may be implanted on the substrate at corresponding substrate locations. This allows ion implantation to be used to provide precise doping profiles advantageous for manufacturing solar cells.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be realized with a system for processing one or more substrates. The system may comprise an ion source for generating ions of desired species, the ions generated from the ion source being directed toward the one or more substrates along an ion beam path; a substrate support for supporting the one or more substrates; a mask disposed between the ion source and the substrate support, the mask comprising a finger defining one or more apertures through which a portion of the ions traveling along the ion beam path pass; and a first detector for detecting ions, the first detector being fixedly positioned relative to the one or more substrates.

Abstract: Techniques for changing temperature of a platen are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for changing temperature of a platen comprising a platen and one or more movable thermal pads comprising one or more thermal fluid channels to carry a thermal fluid configured to affect a temperature of the platen.