Abstract: A method of monitoring contact holes of an integrated circuit using corona charges is provided for determining whether the contact holes are open. The method includes transmitting corona charges over a unit chip having contact holes on a semiconductor wafer; measuring the surface voltage of the unit chip; making a graph illustrating a relationship between the amount of corona charges transmitted and the measured surface voltage of the unit chip; and analyzing the graph to determine whether the contact holes of the unit chip are open. According to the method of the present invention, contact holes may be monitored at an in-line state when manufacturing an integrated circuit by transmitting corona charges onto a unit chip, eliminating the need to use a scanning electronic microscope, thereby preventing a reduction in yield.

Abstract: A method for monitoring an ion implanter includes positioning a substrate behind an interceptor for intercepting a portion of an ion beam to be irradiated toward the substrate, irradiating a first ion beam toward the substrate to form a first shadow on the substrate, rotating the substrate about a central axis of the substrate, irradiating a second ion beam toward the substrate to form a second shadow on the substrate, and measuring a dosage of ions implanted into the substrate to monitor whether the rotation of the substrate has been normally performed. Preferably, a dosage of ions implanted into the substrate is calculated from a thermal wave value of the substrate and whether the rotation of the substrate has been normally performed is monitored by comparing the thermal wave value corresponding to the first shadow with a reference thermal wave value.

Abstract: In a method and an apparatus for inspecting defects on a substrate using a light beam, a light source irradiates light beams having different wavelengths onto the substrate. A detector detects first lights scattered from a surface of the substrate and second lights scattered from impurities on the substrate by irradiation of the light beams. An operation unit compares first intensities of the first lights with second intensities of the second lights in order to produce differential values therebetween, and selects a wavelength corresponding to a maximum value of the differential values. An inspection process for inspecting the defects on the substrate is performed using a light beam having the selected wavelength.

Abstract: For an automatic defect inspection of an edge exposure area of a wafer, an optical unit supplies a light beam onto the edge portion of a wafer and a detection unit detects light reflected from the edge portion. The detection unit converts the detected light into an electrical signal to transmit the electrical signal to a processing unit. The processing unit analyzes the electrical signal to measure the reflectivity of the edge portion, compares the measured reflectivity with a reference reflectivity, and calculates the width of the edge exposure area. The processing unit compares the calculated width with a reference width to detect any defect in the edge exposure area.

Abstract: A method for obtaining an image using a selective combination of wavelengths of light includes dispersing a light in accordance with wavelength bands of the light using a dispersing member, irradiating the dispersed light onto an object to measure reflectivities of the light reflected from the object in accordance with the wavelength bands of the light, comparing reflectivity differences between an objective region and a peripheral region of the object, selecting wavelength bands having the reflectivity differences indicated as either positive values or negative values, adjusting the dispersing member to transmit only the light having the selected wavelength bands, passing light only having the selected wavelength bands through the dispersing member to irradiate the light that has passed through the dispersing member onto the object, taking photographs of the object using the irradiated light, and superposing the photographs of the object to obtain the image of the object.

Abstract: A method and apparatus for detecting contaminants in an ion-implanted wafer by annealing and activating the ion-implanted wafer by heating or charging or both, and measuring the thermal wave absorbance generated from the activated wafer.

Abstract: A method for monitoring an ion implanter includes positioning a substrate behind an interceptor for intercepting a portion of an ion beam to be irradiated toward the substrate, irradiating a first ion beam toward the substrate to form a first shadow on the substrate, rotating the substrate about a central axis of the substrate, irradiating a second ion beam toward the substrate to form a second shadow on the substrate, and measuring a dosage of ions implanted into the substrate to monitor whether the rotation of the substrate has been normally performed. Preferably, a dosage of ions implanted into the substrate is calculated from a thermal wave value of the substrate and whether the rotation of the substrate has been normally performed is monitored by comparing the thermal wave value corresponding to the first shadow with a reference thermal wave value.

Abstract: An apparatus for measuring contamination of a semiconductor substrate includes a chuck for loading a substrate, a position detection means for recognizing a front surface of the loaded substrate to obtain position data of a portion of the substrate to be measured, a first driving part for moving the chuck in accordance with the position data to measure a rear portion of the substrate, and a surface measurement means disposed under the chuck for selectively measuring metal contamination of the substrate at the rear portion of the substrate. In operation, the substrate is loaded onto a chuck, position data of a portion of the substrate to be measured is obtained by recognizing patterns formed on the substrate, the substrate is then moved in accordance with the position data to measure a rear portion of the substrate, and metal contamination is selectively measured at the rear portion of the substrate.

Abstract: A method of measuring a concentration of a material includes irradiating an infrared light onto a substrate having a layer including a first material and dopants, wherein the infrared light is partially absorbed by and partially transmitted through the substrate including the layer. Intensities of the infrared light absorbed in the first material and the dopants are computed according to light wave numbers by utilizing a difference between intensities of the infrared light before and after transmitting the substrate and layer and by utilizing a difference between intensities of the infrared light absorbed in the substrate and layer and absorbed in only the substrate. Concentrations of the dopants are obtained by utilizing a ratio of light wave number regions corresponding to predetermined intensities of infrared light absorbed in the dopants relative to light wave number regions corresponding to the predetermined intensity of infrared light absorbed in the first material.

Abstract: A method and an apparatus for analyzing a portion of a sample, such as a minute pattern formed on a semiconductor substrate, by employing a Fast Fourier Transformation (FFT) method, in which a magnified image of a region of a sample to be analyzed is generated and converted into data having a frequency by the FFT method. The converted data are analyzed to determine whether the region of the sample is normal or abnormal. It is possible to measure and analyze the sample simultaneously and automatically by using the apparatus in accordance with the method for analyzing the sample.

Abstract: An automated and integrated substrate inspecting apparatus for performing an EBR/EEW inspection, a defect inspection of patterns and reticle error inspection of a substrate includes a first stage for supporting a substrate; a first image acquisition unit for acquiring a first image of a peripheral portion of the substrate supported by the first stage; a second stage for supporting the substrate; a second image acquisition unit for acquiring a second image of the substrate supported by the second stage; a transfer robot for transferring the substrate between the first stage and the second stage; and a data processing unit, connected to the first image acquisition unit and the second image acquisition unit, for inspecting results of an edge bead removal process and an edge exposure process performed on the substrate using the first image, and for inspecting for defects of patterns formed on the substrate using the second image.

Abstract: A method for inspecting a polishing pad, an apparatus for performing the method, and a polishing device adopting the apparatus for preventing wafer defects. Polishing pad defects are detected by comparing optical data from a normal polishing pad, which does not cause wafer defects, with optical data from a polishing pad to be inspected. The respective optical data are obtained by radiating a beam into the polishing pad and then collecting and analyzing a beam reflected from the polishing pad.

Abstract: A method of monitoring contact holes of an integrated circuit using corona charges is provided for determining whether the contact holes are open. The method includes transmitting corona charges over a unit chip having contact holes on a semiconductor wafer; measuring the surface voltage of the unit chip; making a graph illustrating a relationship between the amount of corona charges transmitted and the measured surface voltage of the unit chip; and analyzing the graph to determine whether the contact holes of the unit chip are open. According to the method of the present invention, contact holes may be monitored at an in-line state when manufacturing an integrated circuit by transmitting corona charges onto a unit chip, eliminating the need to use a scanning electronic microscope, thereby preventing a reduction in yield.

Abstract: Wafer inspection system and method which are suitable for inspection of highly integrated semiconductor devices. The wafer inspection system includes an apparatus for selectively inspecting conductive pattern defects, which includes a sensor for scanning the surface of a wafer in a noncontact manner and an RLC circuit which is connected to the sensor and converts a signal obtained from the sensor into an electrical characteristic; and an image processing computer which is connected to the apparatus for selectively inspecting conductive pattern defects. Only conductive defects are selectively extracted, thereby increasing inspection efficiency.

Abstract: A method and device detect for the presence of defects, namely micro-scratches, in the surface of a wafer. Light is projected onto a medium at the surface of the wafer, at an angle at which light is not reflected by another layer that may be located under the medium. Light reflected by the surface of the wafer is converted into an electrical signal but any light scattered by the surface is excluded as much as possible from contributing to the formation of the signal. The electric signal corresponds to the intensity of the light reflected from the surface of the wafer. As the light is scanned across the wafer, the values of the electric signal are compared to yield a determination of whether defects are present in the medium. Because the light projected onto the surface of the wafer will be scattered by defects such as micro-scratches, the wafer can be successfully monitored for the existence of such micro-scratches.

Abstract: A method of measuring the thickness of a thin layer, by which the thickness of a top layer formed on the surface of a wafer can be detected in real time, and an apparatus therefor. This method includes irradiating light onto a cell and obtaining luminance from reflected light, detecting the thickness of a thin layer in an oxide site which is adjacent to the cell, repeating the irradiating and detecting steps to obtain a plurality of luminance values from cells formed on the wafer and a plurality of thickness values of thin layers in oxide sites that are adjacent to the cells, and employing a thickness calculation formula for calculating the thickness of a top layer using the plurality of luminance values and plurality of thickness values obtained in the prior steps.

Abstract: A method for correcting color variations on the surface of a wafer, a method for selectively detecting a defect from different patterns, and computer readable recording media for the same are provided. Color variations in images of different parts of a wafer can be corrected using the mean and standard deviation of grey level values for the pixels forming each of the different parts of the wafer. In addition, different threshold values are applied to metal interconnect patterns and spaces of the wafer so that a defect can be selectively detected from the different patterns. Thus, a bridge known as a fatal, or killing defect to a semiconductor device can be detected without also falsely detecting grains as fatal defects. Due to increased defect screening capacity of the methods, the defect detecting method can be further efficiently managed.

Abstract: A method and device detect for the presence of defects, namely micro-scratches, in the surface of a wafer. Light is projected onto a medium at the surface of the wafer, at an angle at which light is not reflected by another layer that may be located under the medium. Light reflected by the surface of the wafer is converted into an electrical signal but any light scattered by the surface is excluded as much as possible from contributing to the formation of the signal. The electric signal corresponds to the intensity of the light reflected from the surface of the wafer. As the light is scanned across the wafer, the values of the electric signal are compared to yield a determination of whether defects are present in the medium. Because the light projected onto the surface of the wafer will be scattered by defects such as micro-scratches, the wafer can be successfully monitored for the existence of such micro-scratches.

Abstract: A method and an apparatus for measuring a step difference in a semiconductor device without making contact with the semiconductor device. A first beam is radiated onto a wafer so as to form a first focus on a first portion of the wafer, and a second beam is radiated onto the wafer so as to form a second focus on a second portion of the wafer. The step difference between the first portion and the second portion of the wafer is measured by calculating a vertical displacement distance of the wafer and a beam focusing device used to attain the first focus and the second focus.

Abstract: A method and apparatus for numerically analyzing a growth degree of grains grown on a surface of a semiconductor wafer, in which the growth degree of grains is automatically calculated and numerated through a computer by using an image file of the surface of the semiconductor wafer scanned by an SEM. A predetermined portion of a surface of the wafer is scanned using the SEM, and the scanned SEM image is simultaneously stored into a database. An automatic numerical program applies meshes to an analysis screen frame and selects an analysis area on a measured image. Thereafter, a smoothing process for reducing an influence of noise is performed on respective pixels designated by the meshes using an average value of image data of adjacent pixels. A standardization process is then performed, based on respective images in order to remove a brightness difference between the measured images.