A wafer inspection system is disclosed. According to certain embodiments, the system includes an electron detector that includes circuitry to detect secondary electrons or backscattered electrons (SE/B SE) emitted from a wafer. The electron beam system also includes a current detector that includes circuitry to detect an electron-beam-induced current (EBIC) from the wafer. The electron beam system further includes a controller having one or more processors and a memory, the controller including circuitry to: acquire data regarding the SE/BSE; acquire data regarding the EBIC; and determine structural information of the wafer based on an evaluation of the SE/BSE data and the EBIC data.

Methods and systems for creating TEM lamella using image restoration algorithms for low keV FIB images are disclosed. An example method includes irradiating a sample with an ion beam at low keV settings, generating a low keV ion beam image of the sample based on emissions resultant from irradiation by the ion beam, and then applying an image restoration model to the low keV ion beam image of the sample to generate a restored image. The sample is then localized within the restored image, and a low keV milling of the sample is performed with the ion beam based on the localized sample within the restored image.

Methods and apparatuses disclosed herein for large-area 3D analysis of samples using glancing incidence FIB milling. An example method at least includes milling, with a focused ion beam, a sample at a shallow angle and at a plurality of rotational orientations to remove a layer of the sample and to expose a surface, and after milling, imaging, with a charged particle beam, the exposed surface of the sample.

A transmission electron microscopy system for imaging a sample, comprising: a pulse generator for generating an initial electron pulse towards the sample, the initial electron pulse to be propagated through the sample to obtain a transmitted electron pulse; an encoding device for encoding the transmitted electron pulse according to a predefined pattern to obtain an encoded electron pulse; a shearing device for temporally shearing the encoded electron pulse in a given direction to obtain a given electron pulse; a detector for detecting the given electron pulse to obtain a single image of the sample; and a datacube generator for determining a spatiotemporal datacube from the single image using the predefined pattern, and outputting the spatiotemporal datacube.

The present invention discloses an imaging device, an imaging method, and an imaging system, belonging to the field of sample image data acquisition and imaging technology. The imaging device includes: a charged particle source, a convergence system, a scanning control system, a detection module, and a spectral analysis module disposed below the detection module, where the detection module includes a plurality of pixelated detector units; and the detection module is provided with a hole thereon. The diffraction pattern is obtained by using the detection module, and the spectral analysis module performs spectral analysis on a charged particle beam passing through the hole, so as to obtain the diffraction pattern and spectral signal simultaneously by one scanning. The imaging method of the present invention is based on a hollow ptychography method, which enables toper form imaging on the diffraction pattern obtained through the detection module, with good imaging effects.

A process for the preparation and imaging of a sample of rock from an oil and gas reservoir is provided. A sample of reservoir rock may be obtained, such as from a core sample obtained using a core sampling tool inserted in a wellbore extending into an oil and gas reservoir. A photoresist may be deposited on the surface of reservoir rock sample to form a homogenous layer. The photoresist-coated surface of the reservoir rock sample may be imaged using a focused ion beam (FIB). The photoresist protects the pores and other surface features of the rock from damage or implantation by the FIB ion beam and thus minimizes the curtain effect in the resulting images.

According to one embodiment, an atom probe inspection device includes one or more processors configured to change a two-dimensional position of a detected ion, detect two-dimensional position information of the ion and a flying time of the ion, identify a type of an element of the ion, generate first information under a first condition and second information under a second condition, and generate a reconstruction image of the sample from the first information and the second information.

The charged particle beam irradiation apparatus includes: a focused ion beam column; an electron beam column; an electron detector; an image forming unit configured to form an observation image based on a signal output from the electron detector; and a control unit configured to repeatedly perform exposure control in which the focused ion beam column is controlled to expose a cross section of a multilayered sample toward a stacking direction with the focused ion beam, the control unit being configured to perform, every time exposure of an observation target layer at a cross section of the multilayered sample is detected in a process of repeatedly performing the exposure control, observation control in which the electron beam column is controlled to radiate the electron beam, and the image forming unit is controlled to form an observation image of the cross section of the multilayered sample.

Methods and systems for acquiring transmission electron microscope video data on a rolling-shutter detector at an enhanced frame rate and without temporal distortions are described. Also described are methods to enhance the dynamic range of image and diffraction data acquired using a transmission electron microscope. The disclosed methods and systems may also be applicable to photon detection and imaging systems.

The present invention relates to an image generation method for an objective for generating an image corresponding to a multi-frame image from image signals obtained by scanning a small number of frames are proposed. To achieve the above objective, there is proposed a method of performing two-dimensionally scanning on an object on a sample with a beam a plurality of times, generating a first image by integrating image signals obtained by a plurality of times of scanning at a first timing among the image signals generated based on the plurality of times of the two-dimensional scanning (S103), generating a second image based on the smaller number of times of scanning than the number of times of scanning at the first timing including scanning after the first timing (S105), training a learning device by using teacher data with the second image as an input and the first image as an output (S108), and inputting input image signals obtained by the smaller number of times of scanning than the number of times of scanning at the first timing to the trained learning device to output an estimated image.