Abstract: Drive mechanisms for solar concentrators, and associated systems and methods are disclosed. A representative solar energy collection system includes an at least partially transparent enclosure, a receiver positioned in the enclosure to receive solar radiation passing into the enclosure, a concentrator positioned within the enclosure to focus incoming solar radiation on the receiver, and a drive system operatively coupled to the concentrator to rotate the concentrator relative to the receiver. The drive system can include a drive chain operatively coupled to the concentrator, a drive gear engaged with the drive chain, and a drive motor coupled to the drive gear to rotate the drive gear and rotate the concentrator relative to the receiver.

Abstract: The invention relates generally to electrodeposition apparatus and methods. When depositing films via electrodeposition, where the substrate has an inherent resistivity, for example, sheet resistance in a thin film, methods and apparatus of the invention are used to electrodeposit materials onto the substrate by forming a plurality of ohmic contacts to the substrate surface and thereby overcome the inherent resistance and electrodeposit uniform films. Methods and apparatus of the invention find particular use in solar cell fabrication.

Abstract: The present invention provides systems and methods for simultaneous, parallel and/or rapid serial testing of material parameters or other parameters of the result of a process. The testing is typically used for screening different methods or materials to select those methods or materials with desired properties. A reactor structure used to form the materials may consist of an array of small isolated reaction chambers that overlie the substrate so that the substrate forms a bottom surface of each isolated reaction chamber. Test structures are formed on the substrate, where the location of each test structure corresponds to an isolated reaction chamber area of the reaction structure. Test structures are used to measure certain parameters, such as by probing contact pads for each test structure, or such testing may be performed in-situ during processing.

Abstract: The present invention provides systems and methods for simultaneous, parallel and/or rapid serial testing of material parameters or other parameters of the result of a process. The testing is typically used for screening different methods or materials to select those methods or materials with desired properties. A reactor structure used to form the materials may consist of an array of small isolated reaction chambers that overlie the substrate so that the substrate forms a bottom surface of each isolated reaction chamber. Test structures are formed on the substrate, where the location of each test structure corresponds to an isolated reaction chamber area of the reaction structure. Test structures are used to measure certain parameters, such as by probing contact pads for each test structure, or such testing may be performed in-situ during processing.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: Substrate processing systems and methods are described for site-isolated processing of substrates. The processing systems include numerous site-isolated reactors (SIRs). The processing systems include a reactor block having a cell array that includes numerous SIRs. A sleeve is coupled to an interior of each of the SIRs. The sleeve includes a compliance device configured to dynamically control a vertical position of the sleeve in the SIR. A sealing system is configured to provide a seal between a region of a substrate and the interior of each of the SIRs. The processing system can include numerous modules that comprise one or more site-isolated reactors (SIRs) configured for one or more of molecular self-assembly and combinatorial processing of substrates.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: A structure for independently supporting a wafer and a mask in a processing chamber is provided. The structure includes a set of extensions for supporting the wafer and a set of extensions supporting the mask. The set of extensions for the wafer and the set of extensions for the mask enable independent movement of the wafer and the mask. In one embodiment, the extensions are affixed to an annular ring which is capable of moving in a vertical direction within the processing chamber. A processing chamber, a mask, and a method for combinatorially processing a substrate are also provided.

Abstract: An integrated processing tool is described comprising a full-wafer processing module and a combinatorial processing module. Chemicals for use in the combinatorial processing module are fed from a delivery system including a set of first manifolds. An output of each first manifold is coupled to at least one mixing vessel. An output of each mixing vessel feeds more than one of a set of second manifolds. An output of each set of second manifolds feeds one of multiple site-isolated reactors of the combinatorial processing module.

Abstract: In embodiments of the current invention, methods of combinatorial processing and a test chip for use in these methods are described. These methods and test chips enable the efficient development of materials, processes, and process sequence integration schemes for semiconductor manufacturing processes. In general, the methods simplify the processing sequence of forming devices or partially formed devices on a test chip such that the devices can be tested immediately after formation. The immediate testing allows for the high throughput testing of varied materials, processes, or process sequences on the test chip. The test chip has multiple site isolated regions where each of the regions is varied from one another and the test chip is designed to enable high throughput testing of the different regions.

Abstract: The invention relates generally to electrodeposition apparatus and methods. When depositing films via electrodeposition, where the substrate has an inherent resistivity, for example, sheet resistance in a thin film, methods and apparatus of the invention are used to electrodeposit materials onto the substrate by forming a plurality of ohmic contacts to the substrate surface and thereby overcome the inherent resistance and electrodeposit uniform films. Methods and apparatus of the invention find particular use in solar cell fabrication.

Abstract: An integrated processing tool is described comprising a full-wafer processing module and a combinatorial processing module. Chemicals for use in the combinatorial processing module are fed from a delivery system including a set of first manifolds. An output of each first manifold is coupled to at least one mixing vessel. An output of each mixing vessel feeds more than one of a set of second manifolds. An output of each set of second manifolds feeds one of multiple site-isolated reactors of the combinatorial processing module.

Abstract: An integrated processing tool is described comprising a full-wafer processing module and a combinatorial processing module. Chemicals for use in the combinatorial processing module are fed from a delivery system including a set of first manifolds. An output of each first manifold is coupled to at least one mixing vessel. An output of each mixing vessel feeds more than one of a set of second manifolds. An output of each set of second manifolds feeds one of multiple site-isolated reactors of the combinatorial processing module.

Abstract: The invention relates generally to methods of repairing defects in thin films. Void defects in thin films are repaired using methods that take advantage of substrate manufacturing protocols rather than conventional superstrate manufacturing protocols. Methods described herein are simple, robust and compatible with existing processes and equipment used in the manufacture of superstrate devices.

Abstract: The invention relates generally to electrodeposition apparatus and methods. When depositing films via electrodeposition, where the substrate has an inherent resistivity, for example, sheet resistance in a thin film, methods and apparatus of the invention are used to electrodeposit materials onto the substrate by forming a plurality of ohmic contacts to the substrate surface and thereby overcome the inherent resistance and electrodeposit uniform films. Methods and apparatus of the invention find particular use in solar cell fabrication.

Abstract: The invention relates generally to electrodeposition apparatus and methods. When depositing films via electrodeposition, where the substrate has an inherent resistivity, for example, sheet resistance in a thin film, methods and apparatus of the invention are used to electrodeposit materials onto the substrate by forming a plurality of ohmic contacts to the substrate surface and thereby overcome the inherent resistance and electrodeposit uniform films. Methods and apparatus of the invention find particular use in solar cell fabrication.

Abstract: An integrated processing tool is described comprising a full-wafer processing module and a combinatorial processing module. Chemicals for use in the combinatorial processing module are fed from a delivery system including a set of first manifolds. An output of each first manifold is coupled to at least one mixing vessel. An output of each mixing vessel feeds more than one of a set of second manifolds. An output of each set of second manifolds feeds one of multiple site-isolated reactors of the combinatorial processing module.

Abstract: An integrated processing tool is described comprising a full-wafer processing module and a combinatorial processing module. Chemicals for use in the combinatorial processing module are fed from a delivery system including a set of first manifolds. An output of each first manifold is coupled to at least one mixing vessel. An output of each mixing vessel feeds more than one of a set of second manifolds. An output of each set of second manifolds feeds one of multiple site-isolated reactors of the combinatorial processing module.