Abstract: An apparatus and method to inspect a defect of a substrate. Since a recess of an under layer of a substrate is darker than a projection of a top layer, a ratio of a value of a secondary electron signal (of an SEM) of the under layer to a value of the top layer may be increased to improve a pattern image used to inspect an under layer defect. Several conditions under which electron beams are irradiated may be set, and the pattern may be scanned under such conditions. Secondary electron signals may be generated according to the conditions and converted into image data to display various pattern images. Scan information on the images may be stored with positional information on the substrate. Each of scan information on the pattern images may be calculated to generate a new integrated image.

Abstract: A method of measuring a step height of a device using a scanning electron microscope (SEM), the method may include providing a device which comprises a first region and a second region, wherein a step is formed between the first region and the second region, obtaining a SEM image of the device by photographing the device using a SEM, wherein the SEM image comprises a first SEM image region for the first region and a second SEM image region for the second region, converting the SEM image into a gray-level histogram and calculating a first peak value related to the first SEM image region and a second peak value related to the second SEM image region, wherein the first peak value and the second peak value are repeatedly calculated by varying a focal length of the SEM, and determining a height of the step by analyzing a trend of changes in the first peak value according to changes in the focal length and a trend of changes in the second peak value according to the changes in the focal length.

Abstract: Microelectronic substrate inspection equipment includes a gas container which contains helium gas, a helium ion generator which is disposed in the gas container and converts the helium gas into helium ions and a wafer stage which is disposed under the gas container and on which a substrate to be inspected is placed. The equipment further includes a secondary electron detector which is disposed above the wafer stage and detects electrons generated from the substrate, a compressor which receives first gaseous nitrogen from a continuous nitrogen supply device and compresses the received first gaseous nitrogen into liquid nitrogen, a liquid nitrogen dewar which is connected to the compressor and stores the liquid nitrogen, and a cooling device that is coupled to the helium ion generator. The cooling device is disposed on the gas container, and cools the helium ion generator by vaporizing the liquid nitrogen. Related methods are also disclosed.

Abstract: In a method of generating a three-dimensional process window qualification, a photoresist layer is coated on a substrate including an underlying structure. A plurality of circular-shaped regions of the substrate are distinguished into 1 to n regions to partition the substrate into a center portion and an edge portion, n being a natural number greater than 2. 1 to n exposing ranges are set, including a common exposing condition for the 1 to n regions. A photoresist pattern is fox led by exposing each shot portion in the 1 to n regions using a split exposing condition in the 1 to n exposing ranges. The photoresist pattern is detected, and a normal photoresist pattern with respect to each of the 1 to n regions is selected to generate the three-dimensional process window qualification.

Abstract: A defect inspection apparatus comprises a table on which a substrate is placed, a first detection unit which is disposed above the table to detect an optical signal from the substrate, a second detection unit which is disposed above the table to detect an electrical signal from the substrate, and a signal processing unit which is connected to the first detection unit and the second detection unit to detect a chemical defect using the optical signal and the electrical signal.

Abstract: In a method of detecting a defect on an object, a preliminary reference image can be obtained from a plurality of comparison regions defined on the object. The preliminary reference image is divided into reference zones by a similar brightness. Each of the reference zones is provided with substantially the same gray level, respectively, to obtain a reference image. Whether a defect exists in an inspection region in the comparison regions is determined using the reference image. Thus, defects in the inspection regions having different brightnesses can be detected using the properly obtained reference image.

Abstract: An apparatus and method to inspect a defect of a substrate. Since a recess of an under layer of a substrate is darker than a projection of a top layer, a ratio of a value of a secondary electron signal (of an SEM) of the under layer to a value of the top layer may be increased to improve a pattern image used to inspect an under layer defect. Several conditions under which electron beams are irradiated may be set, and the pattern may be scanned under such conditions. Secondary electron signals may be generated according to the conditions and converted into image data to display various pattern images. Scan information on the images may be stored with positional information on the substrate. Each of scan information on the pattern images may be calculated to generate a new integrated image.

Abstract: In a method of detecting defects in patterns and an apparatus for performing the method, a first image of a detection region on a semiconductor substrate may be acquired. A second image may be acquired from the first image by performing a Fourier transform and performing a low pass filtering. The second image may be compared with a reference image so that the defects of the detection region are detected. Existence of the defect of the second image is determined using a relation value between a grey level of each of pixels of the second image and the reference image, respectively. When a defect exists, the horizontal and the vertical positions of the pixel where the relation value is minimum are combined to determine the position of the defect.

Abstract: An inspection apparatus and a method for detecting defects in a substrate having a semiconductor device thereon are provided. The method includes establishing a first inspection region including first patterns repeatedly formed in a first direction and a second inspection region including second patterns repeatedly formed in a second direction on the substrate, determining a first unit inspection size of the first inspection region and a second unit inspection size of the second inspection region, obtaining images of the first and second patterns by moving the substrate in the first direction, and detecting defects in the first and second inspection regions by comparing the obtained images of portions of the first and second inspection regions, respectively, with each other. The first inspection size and second inspection size function as comparison units if defects are detected. The substrate may face an image receiving member.

Abstract: In a method of detecting defects of patterns on a semiconductor substrate and an apparatus for performing the method information on positions of reference defects influencing an operation of a circuit including the patterns when the patterns are formed on the semiconductor substrate is acquired in advance. Preliminary defects of the patterns formed on the semiconductor substrate are detected. Positions of the preliminary defects of the patterns are compared with positions of the reference defects. The preliminary defects having the positions substantially the same as the positions of the reference defects are set to be defects of the patterns so that the actual defects are detected.

Abstract: In a method of analyzing a wafer sample, a first defect of a photoresist pattern on the wafer sample having shot regions exposed with related exposure conditions is detected. A first portion of the pattern includes the shot regions exposed with an exposure condition corresponding to a reference exposure condition and a tolerance error range of the reference exposure condition. The first defect repeatedly existing in at least two of the shot regions in a second portion of the pattern is set up as a second defect of the pattern. A first reference image displaying the second defect is obtained. The first defect of the shot regions in the first portion corresponding to the second defect is set up as a third defect corresponding to weak points of the pattern. The exposure conditions of the shot region having no weak points are set up as an exposure margin of an exposure process.

Abstract: An apparatus and method to inspect a defect of a semiconductor device. The amount of secondary electrons generated due to a scanning electron microscope (SEM) may depend on the topology of a pattern of a semiconductor substrate. The amount of secondary electrons emitted from a recess of an under layer is far smaller than that of secondary electrons emitted from a projection of a top layer. Since the recess is darker than the projection, a ratio of a value of a secondary electron signal of the under layer to a value of a secondary electron signal of the top layer may be increased in order to improve a pattern image used to inspect a defect in the under layer. To do this, a plurality of conditions under which electron beams (e-beams) are irradiated may be set, at least two may be selected out of the set conditions, and the pattern may be scanned under the selected conditions.

Abstract: A method for inspection of defects on a substrate includes positioning a probe of a scanning probe microscopy (SPM) over and spaced apart from a substrate, includes scanning the substrate by changing a relative position of the probe with respect to the substrate on a plane spaced apart from and parallel to the substrate, and includes measuring a value of an induced current generated via the probe in at least two different regions of the substrate. The value of the induced current is variable according to at least a shape and a material of the substrate. The method further includes determining whether a defect exists by comparing the values of the induced currents measured in the at least two different regions of the substrate.

Abstract: A method for inspection of defects on a substrate includes positioning a probe of a scanning probe microscopy (SPM) over and spaced apart from a substrate, includes scanning the substrate by changing a relative position of the probe with respect to the substrate on a plane spaced apart from and parallel to the substrate, and includes measuring a value of an induced current generated via the probe in at least two different regions of the substrate. The value of the induced current is variable according to at least a shape and a material of the substrate. The method further includes determining whether a defect exists by comparing the values of the induced currents measured in the at least two different regions of the substrate.

Abstract: A wafer inspecting method including the steps of: multi-scanning a pattern image of a unit inspection region in a normal state and a pattern image of a unit inspection region to be inspected, respectively, using different inspection conditions; comparing the multi-scanned pattern images in the normal state with the multi-scanned pattern images to be inspected obtained by the same inspection conditions, and storing differences between the pattern images as difference images; generating a discrimination difference image by calculating a balance between the stored difference images; and discriminating a defect from noise by using the discrimination difference image.

Abstract: An apparatus and method to inspect a defect of a semiconductor device. The amount of secondary electrons generated due to a scanning electron microscope (SEM) may depend on the topology of a pattern of a semiconductor substrate. The amount of secondary electrons emitted from a recess of an under layer is far smaller than that of secondary electrons emitted from a projection of a top layer. Since the recess is darker than the projection, a ratio of a value of a secondary electron signal of the under layer to a value of a secondary electron signal of the top layer may be increased in order to improve a pattern image used to inspect a defect in the under layer. To do this, a plurality of conditions under which electron beams (e-beams) are irradiated may be set, at least two may be selected out of the set conditions, and the pattern may be scanned under the selected conditions.

Abstract: A surface inspection apparatus and method increase wafer productivity, wherein to increase an efficiency of the surface inspection apparatus to detect defects during a scanning of the wafer surface, a scanning speed for a subsequent defect detection is varied according to an increase/decrease of defect density represented on a plurality of images acquired successively. When the density of defects is reduced, the scanning speed increases and a level of a skip rule increases, and when the density of defects increases, the scanning speed decreases and a level of the skip rule decreases to precisely detect defects, thereby increasing reliability, throughput, and productivity.

Abstract: In a method of detecting a defect on an object, a preliminary reference image can be obtained from a plurality of comparison regions defined on the object. The preliminary reference image is divided into reference zones by a similar brightness. Each of the reference zones is provided with substantially the same gray level, respectively, to obtain a reference image. Whether a defect exists in an inspection region in the comparison regions is determined using the reference image. Thus, defects in the inspection regions having different brightnesses can be detected using the properly obtained reference image.

Abstract: A surface inspection apparatus and method increase wafer productivity, wherein to increase an efficiency of the surface inspection apparatus to detect defects during a scanning of the wafer surface, a scanning speed for a subsequent defect detection is varied according to an increase/decrease of defect density represented on a plurality of images acquired successively. When the density of defects is reduced, the scanning speed increases and a level of a skip rule increases, and when the density of defects increases, the scanning speed decreases and a level of the skip rule decreases to precisely detect defects, thereby increasing reliability, throughput, and productivity.

Abstract: An apparatus for monitoring a photolithography process includes a measurer and a data processor. The measurer measures an optical characteristic of a substrate. The data processor determines defectiveness of the substrate based on the optical the measurer.