There are provided a method of accurately detecting a measurement error of SEM equipment by comparing and aligning a design image with an SEM image, and a method of accurately aligning SEM equipment based on a detected measurement error. The method of detecting a measurement error of SEM equipment includes acquiring SEM images of a measurement target, performing pre-processing on the SEM images and design images corresponding thereto, selecting training SEM images from among the SEM images, performing training by using the training SEM images and training design images and generating a conversion model between the SEM images and the design images, converting the SEM images into conversion design images by using the conversion model, extracting an alignment coordinate value by comparing and aligning the conversion design images with the design images, and determining a measurement error of the SEM equipment based on the alignment coordinate value.

The purpose of the present invention is to provide a pattern matching device and computer program that carry out highly accurate positioning even if edge positions and numbers change. The present invention proposes a computer program and a pattern matching device wherein a plurality of edges included in first pattern data to be matched and a plurality of edges included in second pattern data to be matched with the first pattern data are associated, a plurality of different association combinations are prepared, the plurality of association combinations are evaluated using index values for the plurality of edges, and matching processing is carried out using the association combinations selected through the evaluation.

The present invention provides a packaging unit for liquid sample loading devices applied in an electron microscope. The liquid sample loading devices may be easily, rapidly, precisely and stably aligned and packaged by an engagement of an upper jig and a bottom jig as well as a first fixing pillar supported in a slide track of the packaging unit. Accordingly, efficiency and a yield of packaging the liquid sample loading devices may be improved. In addition, the packaging unit for the liquid sample loading devices of the present invention may directly package a liquid sample, and thus the liquid sample may maintain its original state.

Provided is an ion beam system including a gas field ionization ion source which can obtain a high current sufficient for processing and stabilize an ion beam current. The ion beam system includes a gas field ionization ion source which includes: a vacuum vessel; an emitter tip holder disposed in the vacuum vessel; an emitter tip connected to the emitter tip holder; an extraction electrode opposed to the emitter tip; a gas supply portion for supplying a gas to the emitter tip; and a cold transfer member disposed in the vacuum vessel and transferring cold energy to the emitter tip holder. The cold transfer member has its surface covered with a heat insulating material in order to prevent the gas condensation.

An apparatus for analyzing and/or processing a sample with a particle beam, comprising: a providing unit for providing the particle beam; a shielding element for shielding an electric field (E) generated by charges (Q) accumulated on the sample, wherein the shielding element has a through opening for the particle beam to pass through towards the sample; a detecting unit configured to detect an actual position of the shielding element; and an adjusting unit for adjusting the shielding element from the actual position into a target position.

Disclosed in the embodiments of the present invention is an electron microscope, comprising: an electron source, which is configured to generate an electron beam; a first beam conduit, which is configured to accelerate the electron beam; a second beam conduit, which is configured to accelerate the electron beam; a first detector, which is disposed between the first beam conduit and the second beam conduit and configured to receive secondary electrons generated by the electron beam acting on a sample to be tested; and a control electrode, which is disposed between the first detector and an optical axis of the electron beam and configured to change the direction of movement of backscattered electrons and the secondary electrons generated by the electron beam acting on said sample. By means of the electron microscope provided by the embodiments of the present invention, secondary electrons generated by a pure electron beam acting on a sample to be tested can be detected.

A metrology system is disclosed. In one embodiment, the metrology system includes a controller communicatively coupled to a reference metrology tool and an optical metrology tool, the controller including one or more processors configured to: generate a geometric model for determining a profile of a test HAR structure from metrology data from a reference metrology tool; generate a material model for determining one or more material parameters of a test HAR structure from metrology data from the optical metrology tool; form a composite model from the geometric model and the material model; measure at least one additional test HAR structure with the optical metrology tool; and determine a profile of the at least one additional test HAR structure based on the composite model and metrology data from the optical metrology tool associated with the at least one HAR test structure.

The present invention relates to a method for acquiring tomographic images of a sample in a microscopy system, wherein the sample comprises a defined region, and wherein the method comprises determining a location in three-dimensional space of the defined region, wherein the method further comprises capturing an image of at least a part of the sample, and wherein the determination of the location in three-dimensional space of the defined region is based, at least in part, on the image of the part of the sample. The present invention also relates to a corresponding microscopy system and a computer program product to perform the method according to the present invention.

A vacuum connection mechanism includes: a main body part having a first opening and a first sub opening opened symmetrically in a first direction, and a second opening and a second sub opening opened symmetrically in a second direction; a first bellows connected to the first opening and to the end of which a first flange is provided; a first sub bellows connected to the first sub opening and to the end of which a first blind flange is provided; a first supporting member coupling the first flange and the first blind flange; a second bellows connected to the second opening and to the end of which a second flange is provided; a second sub bellows connected to the second sub opening and to the end of which a second blind flange is provided; and a second supporting member coupling the second flange and the second blind flange.

A scanning electron microscope includes a management computer that generates an irradiation control command of an electron beam, a control block that generates a control signal on the basis of the irradiation control command, and a beam irradiation control device that controls an irradiation direction of the electron beam on the basis of the control signal. The management computer generates the irradiation control command on the basis of a scan type selected by a user and scan parameters set by the use