Abstract: A metallic article for a photovoltaic cell is disclosed. The metallic article includes a first region having a plurality of electroformed elements that are configured to serve as an electrical conduit for a light-incident surface of the photovoltaic cell. A cell-to-cell interconnect is integral with the first region. The cell-to-cell interconnect is configured to extend beyond the light-incident surface and to directly couple the metallic article to a neighboring photovoltaic cell. The cell-to-cell interconnect includes a plurality of electroformed, curved appendages. Each appendage has a first end coupled to an edge of the first region and a second end opposite the first end and away from the edge. The appendages are spaced apart from each other. The metallic article is a unitary, free-standing piece.

Abstract: A system for manufacturing free-standing films from work pieces. The system includes a racetrack structure being configured to transfer at least one work piece and one or more accelerator-based ion implanters coupled to the racetrack structure via an end station. Each of the accelerator-based ion implanters is configured to introduce particles having an energy of greater than 1 MeV to implant into a surface of the work piece loaded in the end station to form a cleave region in the work piece. The system includes one or more cleave modules coupled to the racetrack structure configured to perform a cleave process to release a free-standing film from the work piece along the cleave region. Additionally, the system includes an output port coupled to each cleave module to output the free standing film detached from the work piece and one or more service modules each connected to the racetrack structure.

Abstract: Embodiments of the present invention relate to the use of a particle accelerator beam to form thin films of material from a bulk substrate. In particular embodiments, a bulk substrate having a top surface is exposed to a beam of accelerated particles. Then, a thin film of material is separated from the bulk substrate by performing a controlled cleaving process along a cleave region formed by particles implanted from the beam. To improve uniformity of depth of implantation, channeling effects are reduced by one or more techniques. In one technique, a miscut bulk substrate is subjected to the implantation, such that the lattice of the substrate is offset at an angle relative to the impinging particle beam. According to another technique, the substrate is tilted at an angle relative to the impinging particle beam. In still another technique, the substrate is subjected to a dithering motion during the implantation. These techniques may be employed alone or in combination.

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: A batch processing platform used for ALD or CVD processing is configured for high throughput and minimal footprint. In one embodiment, the processing platform comprises an atmospheric transfer region, at least one batch processing chamber with a buffer chamber and staging platform, and a transfer robot disposed in the transfer region wherein the transfer robot has at least one substrate transfer arm that comprises multiple substrate handling blades. The platform may include two batch processing chambers configured with a service aisle disposed therebetween to provide necessary service access to the transfer robot and the deposition stations. In another embodiment, the processing platform comprises at least one batch processing chamber, a substrate transfer robot that is adapted to transfer substrates between a FOUP and a processing cassette, and a cassette transfer region containing a cassette handler robot. The cassette handler robot may be a linear actuator or a rotary table.

Abstract: Embodiments of the present invention relate to the use of a particle accelerator beam to form thin films of material from a bulk substrate. In particular embodiments, a bulk substrate having a top surface is exposed to a beam of accelerated particles. Then, a thin film of material is separated from the bulk substrate by performing a controlled cleaving process along a cleave region formed by particles implanted from the beam. To improve uniformity of depth of implantation, channeling effects are reduced by one or more techniques. In one technique, a miscut bulk substrate is subjected to the implantation, such that the lattice of the substrate is offset at an angle relative to the impinging particle beam. According to another technique, the substrate is tilted at an angle relative to the impinging particle beam. In still another technique, the substrate is subjected to a dithering motion during the implantation. These techniques may be employed alone or in combination.

Abstract: A batch processing platform used for ALD or CVD processing is configured for high throughput and minimal footprint. In one embodiment, the processing platform comprises an atmospheric transfer region, at least one batch processing chamber with a buffer chamber and staging platform, and a transfer robot disposed in the transfer region wherein the transfer robot has at least one substrate transfer arm that comprises multiple substrate handling blades. The platform may include two batch processing chambers configured with a service aisle disposed therebetween to provide necessary service access to the transfer robot and the deposition stations. In another embodiment, the processing platform comprises at least one batch processing chamber, a substrate transfer robot that is adapted to transfer substrates between a FOUP and a processing cassette, and a cassette transfer region containing a cassette handler robot. The cassette handler robot may be a linear actuator or a rotary table.

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: A system for manufacturing free-standing films from work pieces. The system includes a racetrack structure being configured to transfer at least one work piece and one or more accelerator-based ion implanters coupled to the racetrack structure via an end station. Each of the accelerator-based ion implanters is configured to introduce particles having an energy of greater than 1 MeV to implant into a surface of the work piece loaded in the end station to form a cleave region in the work piece. The system includes one or more cleave modules coupled to the racetrack structure configured to perform a cleave process to release a free-standing film from the work piece along the cleave region. Additionally, the system includes an output port coupled to each cleave module to output the free standing film detached from the work piece and one or more service modules each connected to the racetrack structure.

Abstract: Embodiments of the invention generally provide a method for depositing films using photoexcitation. The photoexcitation may be utilized for at least one of treating the substrate prior to deposition, treating substrate and/or gases during deposition, treating a deposited film, or for enhancing chamber cleaning. In one embodiment, a method for depositing silicon and nitrogen-containing film on a substrate includes heating a substrate disposed in a processing chamber, generating a beam of energy of between about 1 to about 10 eV, transferring the energy to a surface of the substrate; flowing a nitrogen-containing chemical into the processing chamber, flowing a silicon-containing chemical with silicon-nitrogen bonds into the processing chamber, and depositing a silicon and nitrogen-containing film on the substrate.

Abstract: A system of introducing a particle beam such as a linear accelerator particle beam for low contaminate processing. The system includes an accelerator apparatus configured to generate a first particle beam including at least a first ionic specie in an energy level of 1 MeV to 5 MeV or greater. Additionally, the system includes a beam filter coupled to the linear accelerator apparatus to receive the first particle beam. The beam filter is in a first chamber and configured to generate a second particle beam with substantially the first ionic specie only. The first chamber is associated with a first pressure. The system further includes an end-station including a second chamber coupled to the first chamber for extracting the second particle beam. The second particle beam is irradiated onto a planar surface of a bulk workpiece loaded in the second chamber for implanting the first ionic specie. The second chamber is associated with a second pressure that is higher than the first pressure.

Abstract: The present invention generally provides a batch processing system having a processing chamber and a loading chamber. Substrates are transferred in and out the processing chamber in a batch by a substrate boat. A batch handling tool of the present invention is generally used in the loading chamber to load and unload the structured substrate support by group. The batch handling tool generally comprises a support member, which is configured to host at least two sets of support blades. The at least two sets of substrate supports are generally mounted on the support member and their positions are switchable when the support member rotates. Each set of the support blades is configured to load (unload) at least two substrates into(from) the substrate boat.

Abstract: A batch processing platform used for ALD or CVD processing is configured for high throughput and minimal footprint. In one embodiment, the processing platform comprises an atmospheric transfer region, at least one batch processing chamber with a buffer chamber and staging platform, and a transfer robot disposed in the transfer region wherein the transfer robot has at least one substrate transfer arm that comprises multiple substrate handling blades. The platform may include two batch processing chambers configured with a service aisle disposed therebetween to provide necessary service access to the transfer robot and the deposition stations. In another embodiment, the processing platform comprises at least one batch processing chamber, a substrate transfer robot that is adapted to transfer substrates between a FOUP and a processing cassette, and a cassette transfer region containing a cassette handler robot. The cassette handler robot may be a linear actuator or a rotary table.

Abstract: The present invention generally provides a batch processing chamber having a quartz chamber, at least one heater block, an inject assembly coupled to one side of the quartz chamber, and an exhaust assembly coupled to an opposite side of the quartz chamber. In one embodiment, the inject assembly is independently temperature controlled. In another embodiment, at least one temperature sensor is disposed outside the quartz chamber.

Abstract: An apparatus for batch processing of a wafer is disclosed. In one embodiment the batch processing apparatus includes a bell jar furnace having a diffuser disposed between gas inlets and the substrate positioned within the furnace to direct flows within the chamber around the perimeter of the substrate.

Abstract: The present invention generally provides a batch processing system having a processing chamber and a loading chamber. Substrates are transferred in and out the processing chamber in a batch by a substrate boat. A batch handling tool of the present invention is generally used in the loading chamber to load and unload the structured substrate support by group. The batch handling tool generally comprises a support member, which is configured to host at least two sets of support blades. The at least two sets of substrate supports are generally mounted on the support member and their positions are switchable when the support member rotates. Each set of the support blades is configured to load (unload) at least two substrates into(from) the substrate boat.

Abstract: Embodiments of the invention generally provide a method for depositing films using photoexcitation. The photoexcitation may be utilized for at least one of treating the substrate prior to deposition, treating substrate and/or gases during deposition, treating a deposited film, or for enhancing chamber cleaning. In one embodiment, a method for depositing silicon and nitrogen-containing film on a substrate includes heating a substrate disposed in a processing chamber, generating a beam of energy of between about 1 to about 10 eV, transferring the energy to a surface of the substrate; flowing a nitrogen-containing chemical into the processing chamber, flowing a silicon-containing chemical with silicon-nitrogen bonds into the processing chamber, and depositing a silicon and nitrogen-containing film on the substrate.

Abstract: Embodiments of the invention generally provide a method for depositing films using photoexcitation. The photoexcitation may be utilized for at least one of treating the substrate prior to deposition, treating substrate and/or gases during deposition, treating a deposited film, or for enhancing chamber cleaning. In one embodiment, a method for depositing silicon and nitrogen-containing film on a substrate includes heating a substrate disposed in a processing chamber, generating a beam of energy of between about 1 to about 10 eV, transferring the energy to a surface of the substrate; flowing a nitrogen-containing chemical into the processing chamber, flowing a silicon-containing chemical with silicon-nitrogen bonds into the processing chamber, and depositing a silicon and nitrogen-containing film on the substrate.

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: Aspects of the invention include a method and apparatus for processing a substrate using a multi-chamber processing system (e.g., a cluster tool) adapted to process substrates in one or more batch and/or single substrate processing chambers to increase the system throughput. In one embodiment, a system is configured to perform a substrate processing sequence that contains batch processing chambers only, or batch and single substrate processing chambers, to optimize throughput and minimize processing defects due to exposure to a contaminating environment. In one embodiment, a batch processing chamber is used to increase the system throughput by performing a process recipe step that is disproportionately long compared to other process recipe steps in the substrate processing sequence that are performed on the cluster tool. In another embodiment, two or more batch chambers are used to process multiple substrates using one or more of the disproportionately long processing steps in a processing sequence.