An evaluation device includes an X-ray diffraction measuring device configured to acquire a first X-ray locking curve having a first main peak and a first sub-peak partially overlapping the first main peak by measuring an X-ray locking curve of a first portion of a sample having a crystalline material. The evaluation device includes an analysis device configured to separate the first sub-peak from the first main peak, perform first evaluation of a crystal defects or distortion of the sample based on a peak position, peak intensity, or a half width of the separated first sub-peak, and output the first evaluation.

An inspection apparatus and a method of inspecting a semiconductor device are disclosed. The inspection apparatus includes a stage on which a semiconductor device is positioned, a first light source irradiating a high-frequency light onto an inspection area of the semiconductor device to reduce a potential barrier of a PN junction in the semiconductor device, a beam scanner arranged over the semiconductor device and irradiating a charged particle beam onto the inspection area of the semiconductor device to generate secondary electrons, and a defect detector generating a detection image corresponding to the inspection area and detecting, based on a voltage contrast between a reference image and a plurality of detection images, a defect image indicating a defect in the semiconductor device from among the plurality of detection images.

A method of non-destructive detection of surface and near surface abnormalities in a metallic product. The method comprises positioning a sample having a surface under a source of an incident radiation. The surface of the sample is then irradiated with the incident radiation from the source. A scattered radiation is detected and a radiation pattern from the detected scattered radiation is produced. Said radiation pattern is then analysed and the output indicative of the scattered radiation from the sample is produced. Said produced output is then compared with a threshold value, the threshold value indicative of a maximum acceptable detected surface abnormality. Finally, the presence of a surface abnormality is identified when the output exceeds the threshold value.

A method, a non-transitory computer readable medium and a system for focusing an electron beam. The method may include focusing the electron beam on at least one evaluated area of a wafer, based on a height parameter of each one of the at least one evaluated area. The wafer includes a transparent substrate. The height parameter of each one of the at least one evaluated area is determined based on detection signals generated as a result of an illumination of one or more height-measured areas of the wafer with a beam of photons. The illumination occurs while one or more supported areas of the wafer contact one or more supporting elements of a chuck, and while each one of the one or more height-measured areas are spaced apart from the chuck by a distance that exceeds a depth of field of the optics related to the beam of photons.

There is provided a method, a non-transitory computer readable medium, and a system for measuring a pattern. The method can include (a) obtaining an electron image of an area of a sample, the area comprises the pattern, the electron image comprises multiple lines; each line comprises information obtained by moving an electron beam over a scan line; (b) generating a converted image by applying a noise reduction kernel on the electron image, the noise reduction kernel has a width that represents a number of consecutive lines of the electron image; the width is determined based on relationships between analysis results obtained when using noise reduction kernels of different widths; and (c) analyzing the converted image to provide a pattern measurement.

There is provided a method, a non-transitory computer readable medium, and a system for measuring a pattern. The method can include (a) obtaining an electron image of an area of a sample, the area comprises the pattern, the electron image comprises multiple lines; each line comprises information obtained by moving an electron beam over a scan line; (b) generating a converted image by applying a noise reduction kernel on the electron image, the noise reduction kernel has a width that represents a number of consecutive lines of the electron image; the width is determined based on relationships between analysis results obtained when using noise reduction kernels of different widths; and (c) analyzing the converted image to provide a pattern measurement.

There is provided a system and a method comprising obtaining a first (respectively second) image of an area of the semiconductor specimen acquired by an electron beam examination tool at a first (respectively second) illumination angle, determining a plurality of height values informative of a height profile of the specimen in the area, the determination comprising solving an optimization problem which comprises a plurality of functions, each function being representative of a difference between data informative of a grey level intensity at a first location in the first image and data informative of a grey level intensity at a second location in the second image, wherein, for each function, the second location is determined with respect to the first location, or conversely, when solving the optimization problem, wherein a distance between the first and the second locations depends on the height profile, and the first and second illumination angles.

An inspection apparatus and a method of inspecting a semiconductor device are disclosed. The inspection apparatus includes a stage on which a semiconductor device is positioned, a first light source irradiating a high-frequency light onto an inspection area of the semiconductor device to reduce a potential barrier of a PN junction in the semiconductor device, a beam scanner arranged over the semiconductor device and irradiating a charged particle beam onto the inspection area of the semiconductor device to generate secondary electrons, and a defect detector generating a detection image corresponding to the inspection area and detecting, based on a voltage contrast between a reference image and a plurality of detection images, a defect image indicating a defect in the semiconductor device from among the plurality of detection images.

System and method for imaging an integrated circuit (IC). The imaging system comprises an x-ray source including a plurality of spatially and temporally addressable electron sources, an x-ray detector arranged such that incident x-rays are oriented normal to an incident surface of the x-ray detector and a three-axis stage arranged between the x-ray source and the x-ray detector, the three-axis stage configured to have mounted thereon an integrated circuit through which x-rays generated by the x-ray source pass during operation of the imaging system. The imaging system further comprises at least one controller configured to move the three-axis stage during operation of the imaging system and selectively activate a subset of the electron sources during movement of the three-axis stage to acquire a set of intensity data by the x-ray detector as the three-axis stage moves along a three-dimensional trajectory.

A method of detecting an anomaly in a crystallographic structure, the method comprising: illuminating the structure with x-ray radiation in a known direction relative to the crystallographic orientation; positioning the structure such that its crystallographic orientation is known; detecting a pattern of the diffracted x-ray radiation transmitted through the structure; generating the simulated pattern based on the known direction relative to the crystallographic orientation; comparing the detected pattern to a simulated pattern for x-ray radiation illuminating in the known direction; and, detecting the anomaly in the crystallographic structure based on the comparison.