An electron optical system includes an electromagnetic lens configured to include a yoke, and refract an electron beam passing through the yoke by generating a magnetic field, and a shield coil disposed along the inner wall of the yoke, and configured to reduce a leakage magnetic field generated by the electromagnetic lens.

Systems and methods of enhancing imaging resolution by reducing crosstalk between detection elements of a secondary charged-particle detector in a multi-beam apparatus are disclosed. The multi-beam apparatus may comprise an electro-optical system comprising a beam-limit aperture plate having a surface substantially perpendicular to an optical axis, the beam-limit aperture plate comprising a first aperture at a first distance relative to the surface of the beam-limit aperture plate, and a second aperture at a second distance relative to the surface of the beam-limit aperture plate, the second distance being different from the first distance. The first aperture may be a part of a first set of apertures of the beam-limit aperture plate at the first distance, and the second aperture may be a part of a second set of apertures of the beam-limit aperture plate at the second distance.

According to an embodiment, a method for automated critical dimension measurement on a substrate for display manufacturing is provided. The method includes scanning a first field of view having a first size with a charged particle beam to obtain a first image having a first resolution of a first portion of the substrate for display manufacturing; determining a pattern within the first image, the pattern having a first position; scanning a second field of view with the charged particle beam to obtain a second image of a second portion of the substrate, the second field of view has a second size smaller than the first size and has a second position provided relative to the first position, the second image has a second resolution higher than the first resolution; and determining a critical dimension of a structure provided on the substrate from the second image.

A system and a method for measuring of parameter values of semiconductor objects within wafers with increased throughput include using a modified machine learning algorithm to extract measurement results from instances of semiconductor objects. A training method for training the modified machine learning algorithm includes reducing a user interaction. The method can be more flexible and robust and can involve less user interaction than conventional methods. The system and method can be used for quantitative metrology of integrated circuits within semiconductor wafers.

Disclosed are semiconductor inspection apparatuses and methods. The semiconductor inspection apparatus comprises a stage that supports a semiconductor device, a first column that irradiates a first electron beam toward the semiconductor device on the stage, a second column that irradiates a second electron beam toward the semiconductor device, and a detector that detects a secondary electron generated by the second electron beam. The first column is disposed to make a first angle with a top surface of the semiconductor device. The second column is disposed to make a second angle with the top surface of the semiconductor device. The first angle and the second angle are different from each other.

Systems and methods are provided for charged particle detection. The detection system can comprise a signal processing circuit configured to generate a set of intensity gradients based on electron intensity data received from a plurality of electron sensing elements. The detection system can further comprise a beam spot processing module configured to determine, based on the set of intensity gradients, at least one boundary of a beam spot; and determine, based on the at least one boundary, that a first set of electron sensing elements of the plurality of electron sensing elements is within the beam spot. The beam spot processing module can further be configured to determine an intensity value of the beam spot based on the electron intensity data received from the first set of electron sensing elements and also generate an image of a wafer based on the intensity value.

A radiographic image capturing device includes: plural radiation dose detection pixels that respectively output signal values according to a dose of irradiated radiation; a determination unit that determines a presence or absence of defects, block-by-block, based on signal values of radiation dose detection pixels included in each of plural blocks, which are arranged such that the respective blocks include at least a portion of the plural radiation dose detection pixels; a block rearrangement unit that performs block rearrangement to change the arrangement of the plural blocks according to a determination result of the determination unit; and a detection unit that detects a dose of irradiated radiation based on signal values of each arranged block or of each rearranged block.

An electromagnetic compound lens may be configured to focus a charged particle beam. The compound lens may include an electrostatic lens provided on a secondary optical axis and a magnetic lens also provided on the secondary optical axis. The magnetic lens may include a permanent magnet. A charged particle optical system may include a beam separator configured to separate a plurality of beamlets of a primary charged particle beam generated by a source along a primary optical axis from secondary beams of secondary charged particles. The system may include a secondary imaging system configured to focus the secondary beams onto a detector along the secondary optical axis. The secondary imaging system may include the compound lens.

Provided are an image evaluation method and an image evaluation apparatus to evaluate a two-dimensional shape and a change in shape of a pattern side wall of a semiconductor pattern based on a SEM image, thus estimating an exposure condition. To this end, a method and a device include a storage unit that stores a model indicating a relationship between a feature amount that is obtained by creating a plurality of outlines from a SEM image and an exposure condition, and outline creation parameter information corresponding to the model; an outline creation unit that creates a plurality of outlines from a SEM image using the outline creation parameter information; and an estimation unit that uses a feature amount that is found based on the plurality of outlines created by the outline creation unit and the model to find an exposure condition.

An electrostatic chuck control system configured to be utilized during an inspection process of a wafer, the electrostatic chuck control system comprising an electrostatic chuck of a stage configured to be undocked during the inspection process, wherein the electrostatic chuck comprises a plurality of components configured to influence an interaction between the wafer and the electrostatic chuck during the inspection process, a first sensor configured to generate measurement data between at least some of the plurality of components and the wafer, and a controller including circuitry configured to receive the measurement data to determine characteristics of the wafer relative to the electrostatic chuck and to generate adjustment data to enable adjusting, while the stage is undocked, at least some of the plurality of components based on the determined characteristics.