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: 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: The invention relates generally to methods of fabricating photovoltaic stack structures. Methods of the invention find particular use in solar cell fabrication. The performance of a photovoltaic stack can be improved by independent control of fabrication conditions during stack formation, particularly depositing window layers after formation of absorber layers where fabrication conditions of absorber layers would otherwise detrimentally affect quantum grain structures of window layers.

Abstract: The invention relates generally to electrodeposition apparatus and methods. The invention finds particular use in fabricating thin film solar cells. Electrodeposition is improved by using a continuous thin film flow of electrodeposition solution between a substrate and a counter electrode, positioned in close proximity to each other, while the plating current is applied. Apparatus for carrying out methods described herein are highlighted particularly by flow manifolds that allow electrodeposition in the manner described.

Abstract: One embodiment relates to an electron beam apparatus. The apparatus includes a mechanism for moving a substrate relative to the electron beam column at a controlled speed. A probe beam gun is configured to generate a probe beam through the column, and a pre-charging beam gun configured to generate a pre-charging beam through the column. Control circuitry configured to pre-scan a scan line with the pre-charging beam at least once and to subsequently sense scan the scan line with the probe beam at least once. The control circuitry is further configured so that there is a prescribed delay time between said pre-scanning and said sense scanning of the scan line. In another embodiment, a single electron beam and a deflection system configured to deflect the electron beam into pre-scans and sense scans. Other embodiments and features are also disclosed.

Abstract: Disclosed is a semiconductor die having a scanning area. The semiconductor die includes a first plurality of test structures wherein each of the test structures in the first plurality of test structures is located entirely within the scanning area. The semiconductor die further includes a second plurality of test structures wherein each of the test structures in the first plurality of test structures is located only partially within the scanning area. The test structures are arranged so that a scan of the scanning area results in detection of defects outside of the scanning area.

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 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: Disclosed are mechanisms are provided for determining whether a particular integrated circuit (IC) pattern is susceptible to systematic failure, e.g., due to process fluctuations. In one embodiment, final resist patterns for such IC pattern are simulated using a sparse type simulator under various process settings. The sparse type simulator uses a model (e.g., a variable threshold resist model) for a particular photolithography process in which the IC pattern is to be fabricated. The model is generated from measurements taken from a plurality of simulated structures output from a rigorous type simulator. The simulated final resist patterns may then be analyzed to determine whether the corresponding IC pattern is susceptible to systematic failure. After an IC pattern which is susceptible to systematic failure has been found, a test structure may be fabricated from a plurality of IC patterns or cells.

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: Disclosed are techniques for efficiently inspecting defects on voltage contrast test. In one embodiment, methodologies and test structures allow inspection to occur entirely within a charged particle system. In a specific embodiment, a method of localizing and imaging defects in a semiconductor test structure suitable for voltage contrast inspection is disclosed. A charged particle beam based tool is used to determine whether there are any defects present within a voltage contrast test structure. The same charged particle beam based tool is then used to locate defects determined to be present within the voltage contrast test structure. Far each localized defect, the same charged particle beam based tool may then be used to generate a high resolution image of the localized defect whereby the high resolution image can later be used to classify the each defect. In one embodiment, the defect's presence and location are determined without rotating the test structure relative to the charged particle beam.

Abstract: An improved voltage contrast test structure is disclosed. In general terms, the test structure can be fabricated in a single photolithography step or with a single reticle or mask. The test structure includes substructures which are designed to have a particular voltage potential pattern during a voltage contrast inspection. For example, when an electron beam is scanned across the test structure, an expected pattern of intensities are produced and imaged as a result of the expected voltage potentials of the test structure. However, when there is an unexpected pattern of voltage potentials present during the voltage contrast inspection, this indicates that a defect is present within the test structure.

Abstract: An improved voltage contrast test structure is disclosed. In general terms, the test structure can be fabricated in a single photolithography step or with a single reticle or mask. The test structure includes substructures which are designed to have a particular voltage potential pattern during a voltage contrast inspection. For example, when an electron beam is scanned across the test structure, an expected pattern of intensities are produced and imaged as a result of the expected voltage potentials of the test structure. However, when there is an unexpected pattern of voltage potentials present during the voltage contrast inspection, this indicates that a defect is present within the test structure.

Abstract: Disclosed is a semiconductor die having a scanning area. The semiconductor die includes a first plurality of test structures wherein each of the test structures in the first plurality of test structures is located entirely within the scanning area. The semiconductor die further includes a second plurality of test structures wherein each of the test structures in the first plurality of test structures is located only partially within the scanning area. The test structures are arranged so that a scan of the scanning area results in detection of defects outside of the scanning area.

Abstract: Disclosed is test structure that can be fabricated with minimal photolithography masking steps and in which defects may be localized to specific layers. Mechanisms for fabricating such test structures are also provided. In one embodiment, a semiconductor test structure suitable for a voltage contrast inspection is provided. The test structure includes one or more test layers corresponding to one or more product layers selected from a plurality of product layers of an integrated circuit (IC) product structure. The number of the selected one or more test layers is less than a total number of the plurality of product layers of the product structure, and the test layers include at least a first portion that is designed to have a first potential during the voltage contrast inspection and a second portion that is designed to have a second potential during the voltage contrast inspection. The first potential differs from the second potential.

Abstract: Disclosed are methods and apparatus for detecting defects in a partially fabricated semiconductor device with self-aligned contacts. The self-aligned contacts are formed from a first layer with a plurality of contact portions, a second layer with a plurality of conductive lines that are each aligned proximate to an associated underlying contact portion, and a third insulating layer formed over the conductive lines and their proximate underlying contact portions. The third insulating layer has a plurality of vias formed therein that are each formed alongside a one of the conductive lines and over its proximate underlying contact portion. A charged particle beam is scanned over a portion of the vias to form a voltage contrast image of each via. When a minority of the vias in the image have a significantly different brightness level than a majority of the vias, it is then determined that the minority of vias have defects.

Abstract: Disclosed are methods and apparatus for determining whether to perform burn-in on a semiconductor product, such as a product wafer or product wafer lot. In general terms, test structures on the semiconductor product are inspected to extract yield information, such as defect densities. Since this yield information is related to the early or extrinsic instantaneous failure rate, one may then determine the instantaneous extrinsic failure rate for one or more failure mechanisms, such as electromigration, gate oxide breakdown, or hot carrier injection, based on this yield information. It is then determined whether to perform burn-in on the semiconductor product based on the determined instantaneous failure rate.

Abstract: Disclosed are techniques for efficiently inspecting defects on voltage contrast test structures. Improved test structures for facilitating such techniques are also provided. In one embodiment, the methodologies and test structures allow inspection to occur entirely within a charged particle (e.g., e-beam) system, such as a step and repeat e-beam system. In a specific embodiment, a method of localizing and imaging defects in a semiconductor test structure suitable for voltage contrast inspection is disclosed. A charged particle beam based tool is used to determine whether there are any defects (e.g., open or short defects) present within a voltage contrast test structure. The same charged particle beam based tool is then used to locate defects determined to be present within the voltage contrast test structure.

Abstract: A system and method for predicting yield of integrated circuits includes a characterization vehicle (12) having at least one feature representative of at least one type of feature to be incorporated in the final integrated circuit, preferably a device neighborhood, process neighborhood characterization vehicle. The characterization vehicle (12) is subjected to process operations making up the fabrication cycle to be used in fabricating the integrated circuit in order to produce a yield model (16). The yield model (16) embodies a layout as defined by the characterization vehicle (12) and preferably includes features which facilitates the gathering of electrical test data and testing of prototype sections at operating speeds. An extraction engine (18) extracts predetermined layout attributes (26) from a proposed product layout (20).

Abstract: Disclosed are methods and apparatus for efficiently managing IC chip yield learning. In general terms, as each wafer lot moves through fabrication, yield information is obtained from each set of test structures for a particular process or defect mechanism. The nature of the yield information is such that it may be used directly or indirectly to predict product wafer test yield. In one implementation, the yield information includes a systematic yield (Y0), a defect density (DD), and a defect clustering factor (&agr;) determined based on the inspected test structure's yield. A running average of the yield information for each process or defect mechanism is maintained as each wafer lot is processed. As a particular wafer lot moves through the various processes, a product wafer-sort test yield may be predicted at any stage in the fabrication process based on the running-average yield information maintained for previously fabricated wafer lots.