Abstract: An ion implant apparatus configured to measure the temperature or monitor the degradation of components in the apparatus is provided. The ion implant apparatus may include a platen configured to move in a first direction, a mask frame to hold one or more masks disposed on the platen, a first optical sensor configured to project an optical beam to a second optical sensor, and a measurement bar disposed on the mask frame, the measurement bar raised above the surface of the mask frame to interrupt the optical beam when the platen moves in the first direction.

Abstract: A mask alignment system for providing precise and repeatable alignment between ion implantation masks and workpieces. The system includes a mask frame having a plurality of ion implantation masks loosely connected thereto. The mask frame is provided with a plurality of frame alignment cavities, and each mask is provided with a plurality of mask alignment cavities. The system further includes a platen for holding workpieces. The platen may be provided with a plurality of mask alignment pins and frame alignment pins configured to engage the mask alignment cavities and frame alignment cavities, respectively. The mask frame can be lowered onto the platen, with the frame alignment cavities moving into registration with the frame alignment pins to provide rough alignment between the masks and workpieces. The mask alignment cavities are then moved into registration with the mask alignment pins, thereby shifting each individual mask into precise alignment with a respective workpiece.

Abstract: A system for loading workpieces into a process chamber for processing in a matrix configuration includes a conveyor configured to transport multiple workpieces in a linear fashion. A workpiece hotel is configured to receive the multiple workpieces from the conveyor. The workpiece hotel comprises a matrix of cells arranged in N columns and M floors. A pick blade is configured to insert into the hotel and retract from the hotel in order to unload a plurality of substrates from a first floor into a single row of the pick blade, and to repeat the unloading operation to form a matrix comprising a plurality of rows of substrates disposed on the pick blade. In one example, the workpiece hotel has a staggered configuration that provides individual accessibility of each hotel cell.

Abstract: 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 ion implanting a substrate disposed downstream of the ion source with ions generated in an ion source; and disposing a first portion of a mask in front of the substrate to expose the first portion of the mask to the ions, the mask being supported by the first and second mask holders, the mask further comprising a second portion wound in the first mask holder.

Abstract: A carrier capable of holding one or more workpieces is disclosed. The carrier includes movable projections located along the sides of each cell in the carrier. This carrier, in conjunction with a separate alignment apparatus, aligns each workpiece within its respective cell against several alignment pins, using a multiple step alignment process to guarantee proper positioning of the workpiece in the cell. First, the workpieces are moved toward one side of the cell. Once the workpieces have been aligned against this side, the workpieces are then moved toward an adjacent orthogonal side such that the workpieces are aligned to two sides of the cell. Once aligned, the workpiece is held in place by the projections located along each side of each cell. In addition, the alignment pins are also used to align the associated mask, thereby guaranteeing that the mask is properly aligned to the workpiece.

Abstract: A system and method for the handling of workpieces in a workpiece processing system is disclosed. The system utilizes three conveyor belts, where one may be a loading belt, feeding unprocessed workpieces from its associated workpiece carrier to a processing system. A second conveyor belt may be an unloading belt, receiving processed workpieces from the processing system and filling its associated workpiece carrier. The third conveyor belt may be exchanging its workpiece carrier during this time, so that it is available to start operating as the loading belt once all of the workpieces have been removed from the workpiece carrier associated with the first conveyor belt.

Abstract: Glitches during ion implantation of a workpiece, such as a solar cell, can be compensated for. In one instance, a workpiece is implanted during a first pass at a first speed. This first pass results in a region of uneven dose in the workpiece. The workpiece is then implanted during a second pass at a second speed. This second speed is different from the first speed. The second speed may correspond to the entire workpiece or just the region of uneven dose in the workpiece.

Abstract: An ion source includes arc chamber housing defining an arc chamber. The arc chamber housing has an extraction plate in a fixed position, and the extraction plate defines a plurality of extraction apertures. The ion source also includes a shutter assembly positioned outside of the arc chamber proximate the extraction plate. The shutter assembly is configured to block at least a portion of one of the plurality of extraction apertures during one time interval. The ion source combined with relative movement of a workpiece to be treated with an ion beam extracted from the ion source enables a two dimensional ion implantation pattern to be formed on the workpiece using only one ion source.

Abstract: In an ion implanter, an ion current measurement device is disposed behind a mask co-planarly with respect to a surface of a target substrate as if said target substrate was positioned on a platen. The ion current measurement device is translated across the ion beam. The current of the ion beam directed through a plurality of apertures of the mask is measured using the ion current measurement device. In this manner, the position of the mask with respect to the ion beam as well as the condition of the mask may be determined based on the ion current profile measured by the ion current measurement device.

Abstract: A system and method for receiving unprocessed workpieces, moving them, orienting them and placing them in a load lock, or other end point is disclosed. The system includes a gantry module for moving workpieces from a conveyor system to a swap module. The swap module is used to remove a carrier or matrix of processed workpieces from a load lock and place a carrier of matrix of unprocessed workpieces in its place. The processed workpieces are then moved by the gantry module back to the conveyor. The gantry module may have X, Y, Z and rotational actuators and include an end effector having multiple grippers. A method of aligning a plurality of workpieces on the end effector so that the plurality can be transported at the same time is also disclosed.

Abstract: This apparatus has two mask segments. Each mask segment has apertures that an ion beam may pass through. These mask segments can move between a first and second position using hinges. One or more workpieces are disposed behind the mask segments when these mask segments are in a second position. The two mask segments are configured to cover the one or more workpieces in one instance. Ions are implanted into the one or more workpieces through the apertures in the mask segments.

Abstract: An alignment device has a carriage, two rails on the carriage that are configured for a workpiece to pass therebetween, and a finger that protrudes a distance from the carriage. The finger is configured to be disposed on a carrier for the workpieces. The workpieces may be solar cells and may pass through the rails on a conveyor belt. The alignment device may move in order to align the workpieces as the workpieces are loaded into a carrier.

Abstract: In an ion implanter, an ion current measurement device is disposed behind a mask co-planarly with respect to a surface of a target substrate as if said target substrate was positioned on a platen. The ion current measurement device is translated across the ion beam. The current of the ion beam directed through a plurality of apertures of the mask is measured using the ion current measurement device. In this manner, the position of the mask with respect to the ion beam as well as the condition of the mask may be determined based on the ion current profile measured by the ion current measurement device.

Abstract: In an ion implanter, an ion current measurement device is disposed behind a mask co-planarly with respect to a surface of a target substrate as if said target substrate was positioned on a platen. The ion current measurement device is translated across the ion beam. The current of the ion beam directed through a plurality of apertures of the mask is measured using the ion current measurement device. In this manner, the position of the mask with respect to the ion beam as well as the condition of the mask may be determined based on the ion current profile measured by the ion current measurement device.

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 masking apparatus includes a mask positioned upstream of a target positioned for treatment with ions. The mask is sized relative to the target to cause a first half of the target to be treated with a selective treatment of ions through the mask and a second half of the target to be treated with a blanket treatment of ions unimpeded by the mask during a first time interval. The masking apparatus also includes a positioning mechanism to change a relative position of the mask and the target so that the second half of the target is treated with the selective treatment of ions and the first half of the target is treated with the blanket implant during a second time interval. An ion implanter having the masking apparatus is also provided.

Abstract: Glitches during ion implantation of a workpiece, such as a solar cell, can be compensated for. In one instance, a workpiece is implanted during a first pass at a first speed. This first pass results in a region of uneven dose in the workpiece. The workpiece is then implanted during a second pass at a second speed. This second speed is different from the first speed. The second speed may correspond to the entire workpiece or just the region of uneven dose in the workpiece.

Abstract: Methods to form complementary implant regions in a workpiece are disclosed. A mask may be aligned with respect to implanted or doped regions on the workpiece. The mask also may be aligned with respect to surface modifications on the workpiece, such as deposits or etched regions. A masking material also may be deposited on the implanted regions using the mask. The workpiece may be a solar cell.

Abstract: A first species selectively dopes a workpiece to form a first doped region. In one embodiment, a selective implant is performed using a mask with apertures. A soft mask is applied to the first doped region. A second species is implanted into the workpiece to form a second implanted region. The soft mask blocks a portion of the second species. Then the soft mask is removed. The first species and second species may be opposite conductivities such that one is p-type and the other is n-type.

Abstract: A system for loading workpieces into a process chamber for processing in a matrix configuration includes a conveyor configured to transport multiple workpieces in a linear fashion. A workpiece hotel is configured to receive the multiple workpieces from the conveyor. The workpiece hotel comprises a matrix of cells arranged in N columns and M floors. A pick blade is configured to insert into the hotel and retract from the hotel in order to unload a plurality of substrates from a first floor into a single row of the pick blade, and to repeat the unloading operation to form a matrix comprising a plurality of rows of substrates disposed on the pick blade. In one example, the workpiece hotel has a staggered configuration that provides individual accessibility of each hotel cell.