A method for process analysis includes acquiring first inspection data, using a first inspection modality, with respect to a substrate having multiple instances of a predefined pattern of features formed thereon using different, respective sets of process parameters. Characteristics of defects identified in the first inspection data are processed so as to select a first set of defect locations in which the first inspection data are indicative of an influence of the process parameters on the defects. Second inspection data are acquired, using a second inspection modality having a finer resolution than the first inspection modality, of the substrate at the locations in the first set. The defects appearing in the second inspection data are analyzed so as to select, from within the first set of the locations, a second set of the locations in which the second inspection data are indicative of an optimal range of the process parameters.

This method for measuring the misalignment between a first and a second etching zone includes: producing a plasmonic antenna including a first and a second element that are separate and each delineate a cavity on one respective side, all of the elements of the plasmonic antenna that are situated on a first side of a separating plane being produced entirely inside the first zone and all of the elements of the plasmonic antenna that are situated on the second side of the separating plane being produced entirely inside the second zone, and after the production of the plasmonic antenna, the method includes: measuring the absorption rate of the plasmonic antenna, and determining the magnitude of the misalignment between the first and second zones on the basis of the measured absorption rate and of a predicted value for this absorption rate in the absence of a misalignment.

In one embodiment, a charged particle beam writing apparatus includes an estimator calculating an estimated value of a process parameter of a processing device at a scheduled timing at which a substrate as an object of pattern correction is processed in the processing device from a history of the process parameter of the processing device which performs a process after pattern writing, a predictor predicting dimension distribution of a pattern formed on the substrate by the processing device performing the process with the estimated value, a corrector correcting a design dimension based on the predicted dimension distribution, and a writer irradiating the substrate with a charged particle beam and writing the pattern based on the dimension corrected by the corrector.

A charged particle beam writing apparatus includes a writing data generation circuitry to input character information or information of an item selected, for specifying an apparatus quality check pattern used for evaluating apparatus quality of a charged particle beam writing apparatus, and to generate writing data of the apparatus quality check pattern based on the character information or the information of the item selected, and a combination circuitry to input writing data of an actual chip pattern to be written on a target object, and to combine the writing data of the actual chip pattern and the writing data of the apparatus quality check pattern such that the actual chip pattern and the apparatus quality check pattern do not overlap with each other.

The present invention provides apparatus for an imaging system comprising a multitude of chemical emitting elements upon a substrate. In some embodiments the substrate may be approximately round with a radius of approximately one inch. Various methods relating to using and producing an imaging system of chemical emitters are disclosed.

A wafer topography measurement system can be paired with a scanning electron microscope. A topography threshold can be applied to wafer topography data about the wafer, which was obtained with the wafer topography measurement system. A metrology sampling plan can be generated for the wafer. This metrology sampling plan can include locations in the wafer topography data above the topography threshold. The scanning electron microscope can scan the wafer using the metrology sampling plan and identify defects.

In one embodiment, a BAA apparatus 204 includes apertures 3, each of which being provided to blank charged particle beams 20. The apparatus 204 further includes first electrodes 6a, second electrodes 6b, first via plugs 5a, second via plugs 5c, drivers 2 and comparison circuitries 7 that are provided for each aperture 3, wherein a first electrode 6a and a second electrode 6b are opposite to each other, first and second via plug 5a and 5c are electrically connected to the first electrode 6a, a driver 2 supplies a driving signal to the first electrode 6a via the first via plug 5a, and a comparison circuitry 7 is provided to correspond to the first electrode 6a and compares the driving signal and a signal obtained from the second via 5c plug to output a comparison result signal indicating a result of the comparison.

Methods and systems for determining overlay error between different patterned features of a design printed on a wafer in a multi-patterning step process are provided. For multi-patterning step designs, the design for a first patterning step is used as a reference and designs for each of the remaining patterning steps are synthetically shifted until the synthetically shifted designs have the best global alignment with the entire image based on global image-to-design alignment. The final synthetic shift of each design for each patterning step relative to the design for the first patterning step provides a measurement of relative overlay error between any two features printed on the wafer using multi-patterning technology.

This method for measuring the misalignment between a first and a second etching zone includes: producing a plasmonic antenna including a first and a second element that are separate and each delineate a cavity on one respective side, all of the elements of the plasmonic antenna that are situated on a first side of a separating plane being produced entirely inside the first zone and all of the elements of the plasmonic antenna that are situated on the second side of the separating plane being produced entirely inside the second zone, and after the production of the plasmonic antenna, the method includes: measuring the absorption rate of the plasmonic antenna, and determining the magnitude of the misalignment between the first and second zones on the basis of the measured absorption rate and of a predicted value for this absorption rate in the absence of a misalignment.

The present invention provides apparatus for an imaging system comprising a multitude of chemical emitting elements upon a substrate. In some embodiments the substrate may be approximately round with a radius of approximately one inch. Various methods relating to using and producing an imaging system of chemical emitters are disclosed.