Abstract: Arrangements for inspecting a specimen on which plural patterns are formed; capturing a first image of a first area; capturing a second image of a second area in which patterns which are essentially the same with the patterns formed in the first area; creating data relating to corresponding pixels of the first and second images, for each pixel; determining a threshold for each pixel for detecting defects directly in accordance with the first and second images; and detecting defects on the specimen by processing the first and second images by using the threshold for each pixel and information of a scattered diagram of brightness of the first and second images, wherein the threshold is determined by using information of brightness of a local region of at least one of the first and second images, with the local region including an aimed pixel and peripheral pixels of the aimed pixel.

Abstract: The present invention provides a charged particle beam apparatus used to measure micro-dimensions (CD value) of a semiconductor apparatus or the like which captures images for measurement. For the present invention, a sample for calibration, on which a plurality of polyhedral structural objects with known angles on surfaces produced by the crystal anisotropic etching technology are arranged in a viewing field, is used. A beam landing angle at each position within a viewing field is calculated based on geometric deformation on an image of each polyhedral structural object. Beam control parameters for equalizing the beam landing angle at each position within the viewing field are pre-registered. The registered beam control parameters are applied according to the position of the pattern to be measured within the viewing field when performing dimensional measurement.

Abstract: An apparatus for processing a defect candidate image, including: a scanning electron microscope for taking an enlarged image of a specimen by irradiating and scanning a converged electron beam onto the specimen and detecting charged particles emanated from the specimen by the irradiation; an image processor for processing the image taken by the scanning electron microscope to detect defect candidates on the specimen and classify the detected defect candidates into one of plural classes; a memory for storing output from the image processor including images of the detected defect candidates; and a display unit which displays information stored in the memory and an indicator, wherein the display unit displays a distribution of the detected and classified defect candidates in a map format by distinguishing by the classified class, and the display unit also displays an image of a defect candidate stored in the memory together with the map which is indicated on the map by the indicator.

Abstract: A method of inspecting patterns, including: adjusting a brightness of at least one of a first bright field image and a second bright field image detected from a specimen and directed to similar patterns on differing parts of the specimen, so as to more closely match a brightness; comparing the images which are adjusted in brightness to match with each other to detect dissimilarities indicative of a defect of the pattern, wherein in adjusting the brightness, the brightness between the first bright field image and the second bright field image is adjusted by performing a gradation conversion of at least one of the brightness between the first bright field image and the second bright field image; and wherein in the comparing, said defect of the pattern is detected by using information of a scattered diagram of brightness of the first bright field image and the second bright field image.

Abstract: An apparatus for processing a defect candidate image, including: an imager for taking an enlarged image of a specimen; an image processor for processing the image taken by the imager to detect defect candidates existing on the specimen and classify the detected defect candidates into one of plural defect classes; a memory for storing information of the defect candidates including the images of the defect candidates and the classified defect class data outputted from the image processor; and a display unit having a display screen for displaying information stored in the memory, wherein the display unit displays an image of the defect candidates together with the defect class data stored in the memory and the displayed defect class data is changeable on the display screen, and the memory changes the stored defect class data of the displayed defect candidate to the changed defect class data.

Abstract: Disclosed is a scanning electron microscope (SEM) for realizing high-precision dimension measurement of a sample, such as an ArF exposure photoresist, that requires the measurement of a dimension by a low S/N signal waveform. To this end, partial waveforms (or partial images) of sample signal waveforms (or an images) acquired from a dimension measurement target sample and a sample material of the same kind are registered in advance, a measurement target signal waveform (or an image) obtained from the dimension measurement target sample and the sample registration waveform are combined, and a dimension of the dimension measurement target pattern is calculated based on the combination result.

Abstract: The present invention provides a charged particle beam apparatus used to measure micro-dimensions (CD value) of a semiconductor apparatus or the like which captures images for measurement. For the present invention, a sample for calibration, on which a plurality of polyhedral structural objects with known angles on surfaces produced by the crystal anisotropic etching technology are arranged in a viewing field, is used. A beam landing angle at each position within a viewing field is calculated based on geometric deformation on an image of each polyhedral structural object. Beam control parameters for equalizing the beam landing angle at each position within the viewing field are pre-registered. The registered beam control parameters are applied according to the position of the pattern to be measured within the viewing field when performing dimensional measurement.

Abstract: An apparatus for processing a defect candidate image, including: a scanning electron microscope for taking an enlarged image of a specimen by irradiating and scanning a converged electron beam onto the specimen and detecting charged particles emanated from the specimen by the irradiation; an image processor for processing the image taken by the scanning electron microscope to detect defect candidates on the specimen and classify the detected defect candidates into one of plural classes; a memory for storing output from the image processor including images of the detected defect candidates; and a display unit which displays information stored in the memory and an indicator, wherein the display unit displays a distribution of the detected and classified defect candidates in a map format by distinguishing by the classified class, and the display unit also displays an image of a defect candidate stored in the memory together with the map which is indicated on the map by the indicator.

Abstract: To provide a consistent, high-speed, high-precision measurement method based on an electron beam simulation by reflecting the apparatus characteristics of a CD-SEM in an electron beam simulation, the present invention discloses a method for measuring a measurement target pattern with a CD-SEM, the method comprising the steps of performing an electron beam simulation on various target pattern shapes, which is reflected apparatus characteristic and image acquisition conditions; creating SEM simulated waveforms; storing a combination of the created SEM simulated waveforms and pattern shape information corresponding to the created SEM simulated waveforms as a library; comparing an acquired actual electron microscope image with the SEM simulated waveforms; selecting the SEM simulated waveform that is most similar to the actual electron microscope image; and estimating the shape of the measurement target pattern from the pattern shape information corresponding to the selected SEM simulated waveform.

Abstract: A method of evaluating a resolution of a scanning electron microscope includes picking up a first image of a concave and convex pattern formed on a surface of a sample utilizing a first scanning electron microscope, picking up a second image of the concave and convex pattern on the sample utilizing a second scanning electron microscope, respectively processing the first image and the second image in order to evaluate unevenness in resolution between the first scanning electron microscope and the second scanning electron microscope, and determining whether a height of the concave and convex pattern as measured from a bottom thereof is sufficient so that no affection by a secondary electron emitted from the bottom of the concave and convex pattern is exhibited.

Abstract: An exposure process monitoring method capable of performing quantitative monitoring of an exposure amount and a focusing position which are major process parameters during exposure using a Levinson phase shift mask in semiconductor lithography processes is disclosed. During exposure using the Levinson phase shift mask, the focus position is influenceable by optical intensity distribution characteristics so that it can vary from its minus (?) to plus (+) directions by in a way depending upon the pitch width and line width of a line-and-space pattern. In such case, there exist a pattern in which the cross-sectional shape of a resist changes from a forward taper to reverse taper and a pattern in which the sectional shape changes from the reverse to forward taper.

Abstract: It is difficult for a material having low resistance to electron beam irradiation to obtain an electron microscopic image having a high S/N ratio. A conventional image smoothing process can improve stability of measurement, but this process has a problem of measurement errors for absolute values, reduction of sensitivity, deterioration of quality of cubic shape information and the like. In the present invention, by performing an image averaging process without deteriorating cubic shape information of a signal waveform in consideration of dimension deviation of a measurement target pattern, measurement stability is compatible with improvement of precision and sensitivity. Accordingly, it is possible to realize measurement of pattern dimensions and shapes with high precision and control of a highly sensitive semiconductor manufacturing process using the measurement.

Abstract: In the case of monitoring a resolution of a scanning electron microscope, it is required to prepare a sample and to use a measuring algorithm so as to reduce the pattern dependency of an index value of resolution to be measured in order to measure a variation in the size of an electron beam with a high degree of accuracy. According to the present invention, there is used a sample having a sectional shape which is appropriate for monitoring the resolution, that is, the sample has a pattern with such a sectional shape that a side wall of the pattern is inclined so as to prevent an electron beam irradiated on the sample from impinging upon the side wall of the pattern. With this configuration, it is possible carry out such resolution monitor that does not depend upon a sectional shape of a pattern.

Abstract: Disclosed is a scanning electron microscope (SEM) for realizing high-precision dimension measurement of a sample, such as an ArF exposure photoresist, that requires the measurement of a dimension by a low S/N signal waveform. To this end, partial waveforms (or partial images) of sample signal waveforms (or an images) acquired from a dimension measurement target sample and a sample material of the same kind are registered in advance, a measurement target signal waveform (or an image) obtained from the dimension measurement target sample and the sample registration waveform are combined, and a dimension of the dimension measurement target pattern is calculated based on the combination result.

Abstract: In dimension measurement of semiconductor pattern by CD-SEM, the error value between dimensional measurement value and actual dimension on the pattern is much variational as it is dependent on the cross-sectional shape of the pattern, and a low level of accuracy was one time a big problem. In the present invention, a plurality of patterns, each different in shape, were prepared beforehand with AFM measurement result and patterns of the same shape measured by CD-SEM. These measurement results and dimensional errors were homologized with each other and kept in a database. For actual measurement of dimensions, most like side wall shape, and corresponding CD-SEM measurement error result are called up, and the called-up error results are used to correct CD-SME results of measurement object patterns. In this manner, it becomes possible to correct or reduce dimensional error which is dependent on cross-sectional shape of the pattern.

Abstract: The invention provides a system for achieving detection and measurement of film thickness reduction of a resist pattern with high throughput which can be applied to part of in-line process management. By taking into consideration the fact that film thickness reduction of the resist pattern leads to some surface roughness of the upper surface of the resist, a film thickness reduction index value is calculated by quantifying the degree of roughness of the part corresponding to the upper surface of the resist on an electron microscope image of the resist pattern which has been used in the conventional line width measurement. The amount of film thickness reduction of the resist pattern is estimated by applying the calculated index value to a database previously made for relating a film thickness reduction index value to an amount of film thickness reduction of the resist pattern.

Abstract: The present invention is for providing a scanning electron microscope system adapted to output contour information fitting in with the real pattern edge end of a sample, and is arranged to generate a local projection waveform by projecting the scanning electron microscope image in the tangential direction with respect to the pattern edge at each point of the pattern edge of the scanning electron microscope image, estimate the cross-sectional shape of the pattern transferred on the sample by applying the local projection waveform generated at each point to a library, which has previously been created, correlating the cross-sectional shape with the electron beam signal waveform, obtain position coordinate of the edge end fitting in with the cross-sectional shape, and output the contour of the pattern as a range of position coordinates.

Abstract: In SEM image based pattern measurement using electron beam simulation, accuracy of simulation is very influential. For matching between a simulated image and an actual image, it is needed to properly model the shape and material of a target being measured and reflect them in simulated images. In the present invention, highly accurate pattern measurements are achieved by using simulated images with properly set parameters of shape and dimension having a large influence on the accuracy of matching for measurement between simulated and actual images, based on SEM images or information obtained by another measurement apparatus such as AFM.

Abstract: A method of inspecting patterns, including: adjusting a brightness of at least one of a first bright field image and a second bright field image detected from a specimen and directed to similar patterns on differing parts of the specimen, so as to more closely match a brightness; comparing the images which are adjusted in brightness to match with each other to detect dissimilarities indicative of a defect of the pattern, wherein in adjusting the brightness, the brightness between the first bright field image and the second bright field image is adjusted by performing a gradation conversion of at least one of the brightness between the first bright field image and the second bright field image; and wherein in the comparing, said defect of the pattern is detected by using information of a scattered diagram of brightness of the first bright field image and the second bright field image.

Abstract: In the inspection apparatus for a defect of a semiconductor and the method using it for automatically detecting the defect on a semiconductor wafer and presuming the defect occurrence factor using the circuit design data, a plurality of shapes are formed from the circuit design data by deforming the design data with respect to shape deformation items stipulated for respective defect occurrence factor for comparison with the inspection object circuit pattern. The defect is detected by comparison of the group of shapes formed and the actual pattern. Further, the occurrence factors of these defects are presumed, and the defects are classified according to respective factor.