A method of measuring a relative rotational angle includes: shifting an electron beam on a specimen plane by using a deflector; tilting the electron beam with respect to the specimen plane by using the deflector; acquiring a first STEM image including information of a scattering azimuth angle and a second STEM image not including the information of the scattering azimuth angle, before the shifting and the tilting; acquiring a third STEM image including the information of the scattering azimuth angle and a fourth STEM image not including the information of the scattering azimuth angle, after the shifting and the tilting; and obtaining the relative rotational angle based on the first STEM image, the second STEM image, the third STEM image and the fourth STEM image.

A wafer inspection system includes a controller in communication with an electron-beam inspection tool. The controller includes circuitry to: acquire, via an optical imaging tool, coordinates of defects on a sample; set a Field of View (FoV) of the electron-beam inspection tool to a first size to locate a subset of the defects; determine a position of each defect of the subset of the defects based on inspection data generated by the electron-beam inspection tool during a scanning of the sample; adjust the coordinates of the defects based on the determined positions of the subset of the defects; and set the FoV of the electron-beam inspection tool to a second size to locate additional defects based on the adjusted coordinates.

Dynamic band contrast image (DBCI) is constructed with scattering patterns acquired at multiple scanning locations of a sample using a charged particle beam. Each pixel of the DBCI is generated by integrating the corresponding scattering pattern along a diffraction band. The DBCI includes charged particle channeling condition and can be used for detecting sample defects.

A scanning electron microscopy system with improved image beam stability is disclosed. The system includes an electron beam source configured to generate an electron beam and a set of electron-optical elements to direct at least a portion of the electron beam onto a portion of the sample. The system includes an emittance analyzer assembly. The system includes a splitter element configured to direct at least a portion secondary electrons and/or backscattered electrons emitted by a surface of the sample to the emittance analyzer assembly. The emittance analyzer assembly is configured to image at least one of the secondary electrons and/or the backscattered electrons.

A scanning electron microscope objective lens system is disclosed, which includes: a magnetic lens, a deflection device, a deflection control electrode, specimen to be observed, and a detection device; in which, The opening of the pole piece of the magnetic lens faces to the specimen; the deflection device is located in the magnetic lens, which includes at least one sub-deflector; the deflection control electrode is located between the detection device and the specimen, and the deflection control electrode is used to change the direction of the primary electron beam and the signal electrons generating from the specimen; the detection device comprises the first sub-detector for detecting the back-scattered electrons and the second sub-detector for detecting the second electrons. A specimen detection method is also disclosed.

A wafer inspection system includes a controller in communication with an electron-beam inspection tool. The controller includes circuitry to: acquire, via an optical imaging tool, coordinates of defects on a sample; set a Field of View (FoV) of the electron-beam inspection tool to a first size to locate a subset of the defects; determine a position of each defect of the subset of the defects based on inspection data generated by the electron-beam inspection tool during a scanning of the sample; adjust the coordinates of the defects based on the determined positions of the subset of the defects; and set the FoV of the electron-beam inspection tool to a second size to locate additional defects based on the adjusted coordinates.

A charged particle beam device acquires an image by scanning a specimen with a probe formed from a charged particle beam and detects a signal emitted from the specimen. The charged particle beam device includes an optical system that forms the probe; a control unit that repeatedly performs correction processing and image acquisition processing for acquiring a frame image; and an image processing unit that generates an image of the specimen based on a plurality of the frame images. In the correction processing, the control unit acquires a reference image, and corrects the shifting of the irradiation position of the probe. The image processing unit acquires position shift information, corrects a position shift between the frame images based on the position shift information, and generates an image of the specimen based on the plurality of corrected frame images.

The present disclosure proposes a crossover-forming deflector array of an electro-optical system for directing a plurality of electron beams onto an electron detection device. The crossover-forming deflector array includes a plurality of crossover-forming deflectors positioned at or at least near an image plane of a set of one or more electro-optical lenses of the electro-optical system, wherein each crossover-forming deflector is aligned with a corresponding electron beam of the plurality of electron beams.

Methods, systems, and devices for electron beam probing techniques and related structures are described to enable inline testing of memory device structures. Conductive loops may be formed, some of which may be grounded and others of which may be electrically floating in accordance with a predetermined pattern. The loops may be scanned with an electron beam and image analysis techniques may be used to generate an optical pattern. The generated optical pattern may be compared to an expected optical pattern, which may be based on the predetermined pattern of grounded and floating loops. An electrical defect may be determined based on any difference between the generated optical pattern and the expected optical pattern. For example, if a second loop appears as having a brightness corresponding to a grounded loop, this may indicate that an unintended short exists. Fabrication techniques may be adjusted for subsequent devices to correct identified defects.

A scanning electron microscope objective lens system is disclosed, which includes: a magnetic lens, a deflection device, a deflection control electrode, specimen to be observed, and a detection device; in which, The opening of the pole piece of the magnetic lens faces to the specimen; the deflection device is located in the magnetic lens, which includes at least one sub-deflector; the deflection control electrode is located between the detection device and the specimen, and the deflection control electrode is used to change the direction of the primary electron beam and the signal electrons generating from the specimen; the detection device comprises the first sub-detector for detecting the back-scattered electrons and the second sub-detector for detecting the second electrons. A specimen detection method is also disclosed.