Abstract: A method and apparatus for process control in a lithographic process are described. Metrology may be performed on a substrate either before or after performing a patterning process on the substrate. One or more correctables to the lithographic patterning process may be generated based on the metrology. The patterning process performed on the substrate (or a subsequent substrate) may be adjusted with the correctables.

Abstract: A method and apparatus for process control in a lithographic process are described. Metrology may be performed on a substrate either before or after performing a lithographic patterning process on the substrate. One or more correctables to the lithographic patterning process may be generated based on the metrology. The lithographic patterning process performed on the substrate (or a subsequent substrate) may be adjusted with the correctables.

Abstract: It is provided a solar energy module for converting solar radiation to thermal energy. The module includes a thermally insulating element transmissive to solar radiation and having low transmissivity to thermal infra-red radiation, an absorbing element, a sealed enclosure, and a variable portion in the envelope of the sealed enclosure. This portion is adapted for varying the volume available to gas enclosed in the enclosure in accordance with changing temperature of the enclosed gas. Also, it is provided a solar energy module which includes a thermally insulating element, an absorbing surface and liquid pipes for absorbing the solar radiation, and an air duct thermally coupled thereof. The heated liquid and the heated air are usable for a variety of thermal applications. A heat storage may be thermally coupled to the absorbing surface and to the liquid pipes. The air duct has several air valves, and is associated with a controller for regulating air flow through the air duct.

Abstract: The system facilitates dynamically allocating a variable amount of solar radiation to or between multiple solar applications based on optimizing a time-dependent cost function using multiple parameters as inputs to the cost function. Also described is an optical architecture that enables dynamically channeling incident solar radiation to or between multiple solar applications based on the optimization of a cost function. A solar allocation and distribution system includes an allocation sub-system; a distribution sub-system; and a controller configured for controlling the allocation sub-system and the distribution sub-system based on optimizing a cost function, wherein the cost function is time-dependent and based on energy utilization of a facility.

Abstract: Disclosed are techniques, apparatus, and targets for determining overlay error between two layers of a sample. A plurality of targets is provided. Each target includes a portion of the first and second structures and each is designed to have an offset between its first and second structure portions. The targets are illuminated with electromagnetic radiation to thereby obtain spectra from each target at a ?1st diffraction order and a +1st diffraction order.

Abstract: An overlay mark for determining the relative shift between two or more successive layers of a substrate and methods for using such overlay mark are disclosed. In one embodiment, the overlay mark includes at least one test pattern for determining the relative shift between a first and a second layer of the substrate in a first direction. The test pattern includes a first set of working zones and a second set of working zones. The first set of working zones are disposed on a first layer of the substrate and have at least two working zones diagonally opposed and spatially offset relative to one another. The second set of working zones are disposed on a second layer of the substrate and have at least two working zones diagonally opposed and spatially offset relative to one another. The first set of working zones are generally angled relative to the second set of working zones thus forming an “X” shaped test pattern.

Abstract: An overlay method for determining the overlay error of a device structure formed during semiconductor processing is disclosed. The overlay method includes producing calibration data that contains overlay information relating the overlay error of a first target at a first location to the overlay error of a second target at a second location for a given set of process conditions. The overlay method also includes producing production data that contains overlay information associated with a production target formed with the device structure. The overlay method further includes correcting the overlay error of the production target based on the calibration data.

Abstract: A metrology target design may be optimized using inputs including metrology target design information, substrate information, process information, and metrology system information. Acquisition of a metrology signal with a metrology system may be modeled using the inputs to generate one or more optical characteristics of the metrology target. A metrology algorithm may be applied to the characteristics to determine a predicted accuracy and precision of measurements of the metrology target made by the metrology system. Part of the information relating to the metrology target design may be modified and the signal modeling and metrology algorithm may be repeated to optimize the accuracy and precision of the one or more measurements. The metrology target design may be displayed or stored after the accuracy and precision are optimized.

Abstract: Disclosed are techniques, apparatus, and targets for determining overlay error between two layers of a sample. A plurality of targets is provided. Each target includes a portion of the first and second structures and each is designed to have an offset between its first and second structure portions. The targets are illuminated with electromagnetic radiation to thereby obtain spectra from each target at a ?1st diffraction order and a +1st diffraction order.

Abstract: A method and tool for conducting NIR overlay metrology is disclosed. Such methods involve generating a filtered illumination beam including NIR radiation and directing that illumination beam onto an overlay target to produce an optical signal that is detected and used to generate overlay metrology measurements. The method is particularly suited to substrate applications having layers of opaque material that are transmissive in the NIR range (e.g., amorphous carbon) and where NIR imaging is used to obtain overlay measurements. A tool implementation includes a means for generating a filtered illumination beam extending into the NIR range and a detector for receiving NIR signal from an NIR illuminated target and a computer for processing the signal data to obtain overlay metrology measurements.

Abstract: Disclosed are techniques, apparatus, and targets for determining overlay error between two layers of a sample. Target A is designed to have an offset Xa between its first and second structures portions; target B is designed to have an offset Xb; target C is designed to have an offset Xc; and target D is designed to have an offset Xd. Each of the offsets Xa, Xb, Xc and Xd is preferably different from zero; Xa is an opposite sign and differ from Xb; and Xc is an opposite sign and differs from Xd. The targets A, B, C and D are illuminated with electromagnetic radiation to obtain spectra SA, SB, SC, and SD from targets A, B, C, and D, respectively. Any overlay error between the first structures and the second structures is then determined using a linear approximation based on the obtained spectra SA, SB, SC, and SD.

Abstract: Metrology may be implemented during semiconductor device fabrication by a) modeling a first measurement on a first test cell formed in a layer of a partially fabricated device; b) performing a second measurement on a second test cell in the layer; c) feeding information from the second measurement into the modeling of the first measurement; and after a lithography pattern has been formed on the layer including the first and second test cells, d) modeling a third and a fourth measurement on the first and second test cells respectively using information from a) and b) respectively.

Abstract: An overlay mark for determining the relative shift between two or more successive layers of a substrate and methods for using such overlay mark are disclosed. In one embodiment, the overlay mark includes at least one test pattern for determining the relative shift between a first and a second layer of the substrate in a first direction. The test pattern includes a first set of working zones and a second set of working zones. The first set of working zones are disposed on a first layer of the substrate and have at least two working zones diagonally opposed and spatially offset relative to one another. The second set of working zones are disposed on a second layer of the substrate and have at least two working zones diagonally opposed and spatially offset relative to one another. The first set of working zones are generally angled relative to the second set of working zones thus forming an “X” shaped test pattern.

Abstract: A resultant image of a grating target may be obtained by dividing an image of the target into first and second portions and optically modifying the first and/or second portion such that a final image formed from their combination is characterized by a Moiré pattern. The resultant image may be analyzed to determine a shift in the grating target from a shift in the Moiré pattern. Optical alignment apparatus may include a first beam splitter, an image transformation element optically coupled to the first beam splitter, and a second beam splitter. The first beam splitter divides an image of a grating target into first and second portions. The second beam splitter combines the first portion and the second portion. The image transformation element optically modifies the first and/or second portion such that a final image formed from their combination is characterized by a Moiré pattern.

Abstract: The invention is a method for generating a design rule map having a spatially varying overlay error budget. Additionally, the spatially varying overlay error budget can be employed to determine if wafers are fabricated in compliance with specifications. In one approach a design data file that contains fabrication process information and reticle information is processed using design rules to obtain a design map with a spatially varying overlay error budget that defines a localized tolerance to overlay errors for different spatial locations on the design map. This spatially varying overlay error budget can be used to disposition wafers. For example, overlay information obtained from measured metrology targets on a fabricated wafer are compared with the spatially varying overlay error budget to determine if the wafer overlay satisfies the required specification.

Abstract: A method and apparatus for process control in a lithographic process are described. Metrology may be performed on a substrate either before or after performing a lithographic patterning process on the substrate. One or more correctables to the lithographic patterning process may be generated based on the metrology. The lithographic patterning process performed on the substrate (or a subsequent substrate) may be adjusted with the correctables.

Abstract: A resultant image of a grating target may be obtained by dividing an image of the target into first and second portions and optically modifying the first and/or second portion such that a final image formed from their combination is characterized by a Moiré pattern. The resultant image may be analyzed to determine a shift in the grating target from a shift in the Moiré pattern. Optical alignment apparatus may include a first beam splitter, an image transformation element optically coupled to the first beam splitter, and a second beam splitter. The first beam splitter divides an image of a grating target into first and second portions. The second beam splitter combines the first portion and the second portion. The image transformation element optically modifies the first and/or second portion such that a final image formed from their combination is characterized by a Moiré pattern.

Abstract: Methods and apparatus for producing a semiconductor. A production reticle having a pattern that includes circuit features, phase shift target structures and overlay target structures is provided. The pattern is transferred multiple times across a test wafer surface for various focus levels to form a focus matrix. The pattern shift of the phase shift target structures is measured using an overlay metrology tool. The phase difference is calculated for each phase shift target structure, based on the pattern shift and the phase shift target structure focus level to qualify the phase difference of the production reticle. The pattern is transferred onto a production wafer when the phase difference meets desired limits. The pattern shift of the overlay target structures transferred to the production wafer is measured using an overlay metrology tool. The pattern placement error of the overlay target structures is calculated and the pattern placement error is qualified.

Abstract: Disclosed are techniques, apparatus, and targets for determining overlay error between two layers of a sample. In one embodiment, a method for determining overlay between a plurality of first structures in a first layer of a sample and a plurality of second structures in a second layer of the sample is disclosed. Targets A, B, C and D that each include a portion of the first and second structures are provided. Target A is designed to have an offset Xa between its first and second structures portions; target B is designed to have an offset Xb between its first and second structures portions; target C is designed to have an offset Xc between its first and second structures portions; and target D is designed to have an offset Xd between its first and second structures portions. Each of the offsets Xa, Xb, Xc and Xd is preferably different from zero; Xa is an opposite sign and differ from Xb; and Xc is an opposite sign and differs from Xd.

Abstract: An overlay mark for determining the relative position between two or more successive layers of a substrate or between two or more separately generated patterns on a single layer of a substrate is disclosed. The overlay mark includes a plurality of coarsely segmented lines that are formed by a plurality of finely segmented bars. In some cases, the coarsely segmented lines also include at least one dark field while being separated by a plurality of finely segmented bars and at least one clear field. In other cases, the coarsely segmented lines are positioned into at least two groups. The first group of coarsely segmented lines, which are separated by clear fields, are formed by a plurality of finely segmented bars. The second group of coarsely segmented lines, which are separated by dark fields, are also formed by a plurality of finely segmented bars.