Abstract: Techniques for processing a substrate are disclosed. In one exemplary embodiment, the technique may be realized with an ion implantation system for processing a substrate.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be realized as a method for processing a substrate. The method may comprise directing an ion beam comprising a plurality of ions along an ion beam path, from an ion source to the substrate; disposing at least a portion of a mask in the ion beam path, between the ion source and the substrate; and translating one of the substrate and the mask relative to other one of the substrate and the mask.

Abstract: Techniques for processing a substrate are disclosed. In one exemplary embodiment, the technique may be realized as a method for processing a substrate, the method comprising: ionizing first material and second material in an ion source chamber of an ion source, the first material being boron (B) containing material, the second material being one of phosphorous (P) containing material and arsenic (As) containing material; generating first ions containing B and second ions containing one of P and As; and extracting the first and second ions from the ion source chamber and directing the first and second ions toward the substrate.

Abstract: Techniques for processing a substrate are disclosed. In one exemplary embodiment, the technique may be realized as a method for processing a substrate, the method comprising: ionizing first material and second material in an ion source chamber of an ion source, the first material being boron (B) containing material, the second material being one of phosphorous (P) containing material and arsenic (As) containing material; generating first ions containing B and second ions containing one of P and As; and extracting the first and second ions from the ion source chamber and directing the first and second ions toward the substrate.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be achieved using a mask for processing the substrate. The mask may be incorporated into a substrate processing system such as, for example, an ion implantation system. The mask may comprise one or more first apertures disposed in a first row; and one or more second apertures disposed in a second row, each row extending along a width direction of the mask, wherein the one or more first apertures and the one or more second apertures are non-uniform.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be achieved using a mask for processing the substrate. The mask may be incorporated into a substrate processing system such as, for example, an ion implantation system. The mask may comprise a first base; and a plurality of fingers spaced apart from one another to define one or more gaps.

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: A plasma processing apparatus comprises a plasma source configured to produce a plasma in a plasma chamber, such that the plasma contains ions for implantation into a workpiece. The apparatus also includes a focusing plate arrangement having an aperture arrangement configured to modify a shape of a plasma sheath of the plasma proximate the focusing plate such that ions exiting an aperture of the aperture arrangement define focused ions. The apparatus further includes a processing chamber containing a workpiece spaced from the focusing plate such that a stationary implant region of the focused ions at the workpiece is substantially narrower that the aperture. The apparatus is configured to create a plurality of patterned areas in the workpiece by scanning the workpiece during ion implantation.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be achieved using a mask for processing the substrate. The mask may be incorporated into a substrate processing system such as, for example, an ion implantation system. The mask may comprise one or more first apertures disposed in a first row; and one or more second apertures disposed in a second row, each row extending along a width direction of the mask, wherein the one or more first apertures and the one or more second apertures are non-uniform.

Abstract: A method of controlling operation of an indirectly-heated cathode (IHC) ion source includes a step of measuring a rate of loss of cathode weight of the IHC ion source that occurs during operation using a first cathode configuration and under a first set of operation conditions. A maximum weight loss for the first cathode configuration is determined, and a cathode lifetime is calculated based upon the rate of cathode weight loss and the maximum weight loss. A further method includes receiving a minimum source bias power value for operation of a cathode in a first configuration, measuring a rate of decrease in source bias power for a cathode in the first configuration, and calculating a lifetime of the cathode based upon the minimum source bias power and rate of decrease in source bias power.

Abstract: Methods of reducing glitch rates within an ion implanter are described. In one embodiment, a plasma-assisted conditioning is performed, wherein the bias voltage to the extraction electrodes is modified so as to inhibit the formation of an ion beam. The power supplied to the plasma generator in the ion source is increased, thereby creating a high density plasma, which is not extracted by the extraction electrodes. This plasma extends from the arc chamber through the extraction aperture. Energetic ions then condition the extraction electrodes. In another embodiment, a plasma-assisted cleaning is performed. In this mode, the extraction voltage applied to the arc chamber body is modulated between two voltages so as to clean both the extraction electrodes and the faceplate of the arc chamber body.

Abstract: An ion implantation system including a plasma source, a mask-slit, and a plasma chamber. The plasma source is configured to generate a plasma within the plasma chamber in response to the introduction of a gas therein. The mask-slit is electrically isolated from the plasma chamber. A positive voltage bias is applied to the plasma chamber above a bias potential used to generate the plasma. The positive voltage bias drives the plasma potential to accelerate the ions to a desired implant energy. The accelerated ions pass through an aperture in the mask-slit and are directed toward a substrate for implantation. The mask-slit is electrically isolated from the plasma chamber and is maintained at ground potential with respect to the plasma.

Abstract: A bracket for gathering and retaining flexible conduits and including a superstructure having an upper frame and lower extending stem. A pedestal seating the stem so that the frame is supported thereupon, with an underside of the pedestal adhering to a location associated with an application to which the conduits are related and in order to prevent bending or kinking of the hoses.

Abstract: A system for implanting a substrate. The system includes a substrate holder disposed within a process chamber of the system and coupled to ground. The system also includes an electrode disposed within the process chamber and coupled to a power source, the power source configured to supply voltage to the electrode as an unbalanced voltage pulse train, wherein a negative peak voltage during a negative voltage pulse period of the unbalanced voltage pulse train is higher than a positive peak voltage during a positive voltage pulse period of the unbalanced pulse train. The system further includes a movable mask, wherein the movable mask is configured to move between a first position proximate the substrate holder, and a second position proximate the driven electrode.

Abstract: A plasma processing apparatus comprises a plasma source configured to produce a plasma in a plasma chamber, such that the plasma contains ions for implantation into a workpiece. The apparatus also includes a focusing plate arrangement having an aperture arrangement configured to modify a shape of a plasma sheath of the plasma proximate the focusing plate such that ions exiting an aperture of the aperture arrangement define focused ions. The apparatus further includes a processing chamber containing a workpiece spaced from the focusing plate such that a stationary implant region of the focused ions at the workpiece is substantially narrower that the aperture. The apparatus is configured to create a plurality of patterned areas in the workpiece by scanning the workpiece during ion implantation.

Abstract: A system for implanting a substrate. The system includes a substrate holder disposed within a process chamber of the system and coupled to ground. The system also includes an electrode disposed within the process chamber and coupled to a power source, the power source configured to supply voltage to the electrode as an unbalanced voltage pulse train, wherein a negative peak voltage during a negative voltage pulse period of the unbalanced voltage pulse train is higher than a positive peak voltage during a positive voltage pulse period of the unbalanced pulse train. The system further includes a movable mask, wherein the movable mask is configured to move between a first position proximate the substrate holder, and a second position proximate the driven electrode.

Abstract: A method of controlling operation of an indirectly-heated cathode (IHC) ion source comprises a step of measuring a rate of loss of cathode weight of the IHC ion source that occurs during operation using a first cathode configuration and under a first set of operation conditions. A maximum weight loss for the first cathode configuration is determined, and a cathode lifetime is calculated based upon the rate of cathode weight loss and the maximum weight loss. A further method comprises receiving a minimum source bias power value for operation of a cathode in a first configuration, measuring a rate of decrease in source bias power for a cathode in the first configuration, and calculating a lifetime of the cathode based upon the minimum source bias power and rate of decrease in source bias power.

Abstract: To achieve cost efficiency, solar cells must be processed at a high throughput. Breakages, which may leave debris on the clamping surface of the platen, adversely affect this throughput. A plurality of embodiments are disclosed which may be used to remove debris from the clamping surface without breaking the vacuum condition within the processing station. In some embodiments, a brush is used to sweep the debris from the surface of the platen. In other embodiments, an adhesive material is used to collect the debris. In some embodiments, the automation equipment used to handle masks may also be used to handle the platen cleaning mechanisms. In still other embodiments, stream of gas or ion beams are used to clean debris from the clamping surface of the platen.

Abstract: A plasma processing apparatus comprises a plasma source configured to produce a plasma in a plasma chamber, such that the plasma contains ions for implantation into a workpiece. The apparatus also includes a focusing plate arrangement having an aperture arrangement configured to modify a shape of a plasma sheath of the plasma proximate the focusing plate such that ions exiting an aperture of the aperture arrangement define focused ions. The apparatus further includes a processing chamber containing a workpiece spaced from the focusing plate such that a stationary implant region of the focused ions at the workpiece is substantially narrower that the aperture. The apparatus is configured to create a plurality of patterned areas in the workpiece by scanning the workpiece during ion implantation.

Abstract: Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be realized as a method for processing a substrate. The method may comprise directing an ion beam comprising a plurality of ions along an ion beam path, from an ion source to the substrate; disposing at least a portion of a mask in the ion beam path, between the ion source and the substrate; and translating one of the substrate and the mask relative to other one of the substrate and the mask.