Abstract: The inventive concept provides apparatuses and methods for monitoring semiconductor fabrication processes in real time using polarized light. In some embodiments, the apparatus comprises a light source configured to generate light, a beam splitter configured to reflect the light toward the wafer being processed, an objective polarizer configured to polarize the light reflected toward the wafer and to allow light reflected by the wafer to pass therethrough, a blaze grating configured to separate light reflected by the wafer according to wavelength, an array detector configured to detect the separated light and an analyzer to analyze the three-dimensional profile of the structure/pattern being formed in the wafer.

Abstract: The inventive concept provides apparatuses and methods for monitoring semiconductor fabrication processes in real time using polarized light. In some embodiments, the apparatus comprises a light source configured to generate light, a beam splitter configured to reflect the light toward the wafer being processed, an objective polarizer configured to polarize the light reflected toward the wafer and to allow light reflected by the wafer to pass therethrough, a blaze grating configured to separate light reflected by the wafer according to wavelength, an array detector configured to detect the separated light and an analyzer to analyze the three-dimensional profile of the structure/pattern being formed in the wafer.

Abstract: The inventive concept provides apparatuses and methods for monitoring semiconductor fabrication processes in real time using polarized light. In some embodiments, the apparatus comprises a light source configured to generate light, a beam splitter configured to reflect the light toward the wafer being processed, an objective polarizer configured to polarize the light reflected toward the wafer and to allow light reflected by the wafer to pass therethrough, a blaze grating configured to separate light reflected by the wafer according to wavelength, an array detector configured to detect the separated light and an analyzer to analyze the three-dimensional profile of the structure/pattern being formed in the wafer.

Abstract: Methods of analyzing photolithography processes are provided. The methods may include obtaining an image from a pattern formed on a wafer and obtaining dimensions of the image. The methods may further include converting the dimensions into a profile graph and then dividing the profile graph into a low-frequency band profile graph and a high-frequency band profile graph.

Abstract: Methods and apparatuses for measuring parameters of integrated circuit devices may be provided. The methods may include performing detecting operations on samples to obtain a set of data. Each detecting operation may include irradiating a light beam to the samples using a light irradiation part and detecting reflected light from the samples using a light detector. The samples may have values of a parameter different from one another. The method may also include obtaining a principal component based on the set of data and obtaining a regression model for the parameter using the principal component and values of the parameter of the samples.

Abstract: A method of monitoring a semiconductor fabrication process including forming a barrier pattern on a substrate, forming a sacrificial pattern on the barrier pattern, removing the sacrificial pattern to expose a surface of the barrier pattern, generating photoelectrons by irradiating X-rays to a surface of the substrate, and inferring at least one material existing on the surface of the substrate by collecting and analyzing the photoelectrons may be provided.

Abstract: A method for detecting defects includes irradiating at least one electron beam into a first region of a substrate, irradiating at least one electron beam into a second region electrically connected to the first region, and detecting secondary electrons emitted from the second region. The electron beam irradiated into the first region may be the same or different from the electron beam irradiated into the second region. Alternatively, different beams may be simultaneously irradiated into the first and second regions. An image generated based on the secondary electrons shows a defect in the substrate as a region having a grayscale difference with other regions in the image.

Abstract: Apparatuses and methods for extracting defect depth information and methods of improving semiconductor device manufacturing processes using defect depth information are provided. The apparatuses may include an inspection assembly configured to obtain a plurality of optical images of a portion of an inspection object including a defect along a depth direction and a processor circuit configured to generate defect data using the plurality of optical images and provide defect depth information by comparing the defect data with comparison data in a library database.

Abstract: A method for detecting defects includes irradiating at least one electron beam into a first region of a substrate, irradiating at least one electron beam into a second region electrically connected to the first region, and detecting secondary electrons emitted from the second region. The electron beam irradiated into the first region may be the same or different from the electron beam irradiated into the second region. Alternatively, different beams may be simultaneously irradiated into the first and second regions. An image generated based on the secondary electrons shows a defect in the substrate as a region having a grayscale difference with other regions in the image.

Abstract: The inventive concept provides apparatuses and methods for monitoring semiconductor fabrication processes in real time using polarized light. In some embodiments, the apparatus comprises a light source configured to generate light, a beam splitter configured to reflect the light toward the wafer being processed, an objective polarizer configured to polarize the light reflected toward the wafer and to allow light reflected by the wafer to pass therethrough, a blaze grating configured to separate light reflected by the wafer according to wavelength, an array detector configured to detect the separated light and an analyzer to analyze the three-dimensional profile of the structure/pattern being formed in the wafer.

Abstract: Methods of analyzing photolithography processes are provided. The methods may include obtaining an image from a pattern formed on a wafer and obtaining dimensions of the image. The methods may further include converting the dimensions into a profile graph and then dividing the profile graph into a low-frequency band profile graph and a high-frequency band profile graph.

Abstract: A method forms an ultimate or final image of a sample by selecting some of a plurality of image frames and integrating the selected frames. The method includes providing a semiconductor device including a region of interest and a peripheral region; obtaining a plurality of image frames each including a region of interest image and a peripheral region image respectively corresponding to the region of interest and the peripheral region; selecting at least some of the plurality of image frames based on a contrast between the region of interest image and the peripheral region image; and obtaining an image of the semiconductor device by integrating the selected image frames.