According to one aspect of the present invention, a multi-beam image acquisition apparatus, includes: an objective lens configured to image multiple primary electron beams on a substrate by using the multiple primary electron beams; a separator configured to have two or more electrodes for forming an electric field and two or more magnetic poles for forming a magnetic field and configured to separate multiple secondary electron beams emitted due to the substrate being irradiated with the multiple primary electron beams from trajectories of the multiple primary electron beams by the electric field and the magnetic field formed; a deflector configured to deflect the multiple secondary electron beams separated; a lens arranged between the objective lens and the deflector and configured to image the multiple secondary electron beams at a deflection point of the deflector; and a detector configured to detect the deflected multiple secondary electron beams.

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

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

A fast method of imaging a 2D sample with a multi-beam particle microscope includes the following steps: providing a layer of the 2D sample; determining a feature size of features included in the layer; determining a pixel size based on the determined feature size in the layer; determining a beam pitch size between individual beams in the layer based on the determined pixel size; and imaging the layer of the 2D sample with a setting of the multi-beam particle microscope based on the determined pixel size and based on the determined beam pitch size.

A fast method of imaging a 2D sample with a multi-beam particle microscope includes the following steps: providing a layer of the 2D sample; determining a feature size of features included in the layer; determining a pixel size based on the determined feature size in the layer; determining a beam pitch size between individual beams in the layer based on the determined pixel size; and imaging the layer of the 2D sample with a setting of the multi-beam particle microscope based on the determined pixel size and based on the determined beam pitch size.

A detector may be provided with an array of sensing elements. The detector may include a semiconductor substrate including the array, and a circuit configured to count a number of charged particles incident on the detector. The circuit of the detector may be configured to process outputs from the plurality of sensing elements and increment a counter in response to a charged particle arrival event on a sensing element of the array. Various counting modes may be used. Counting may be based on energy ranges. Numbers of charged particles may be counted at a certain energy range and an overflow flag may be set when overflow is encountered in a sensing element. The circuit may be configured to determine a time stamp of respective charged particle arrival events occurring at each sensing element. Size of the sensing element may be determined based on criteria for enabling charged particle counting.

A detector may be provided with an array of sensing elements. The detector may include a semiconductor substrate including the array, and a circuit configured to count a number of charged particles incident on the detector. The circuit of the detector may be configured to process outputs from the plurality of sensing elements and increment a counter in response to a charged particle arrival event on a sensing element of the array. Various counting modes may be used. Counting may be based on energy ranges. Numbers of charged particles may be counted at a certain energy range and an overflow flag may be set when overflow is encountered in a sensing element. The circuit may be configured to determine a time stamp of respective charged particle arrival events occurring at each sensing element. Size of the sensing element may be determined based on criteria for enabling charged particle counting.

A particle detector according to one embodiment includes: superconductive lines, conductive lines, insulating films, a first detection circuit, and a second detection circuit. The superconductive lines extend in a first direction and are arranged in a second direction intersecting the first direction. The conductive lines extend in a third direction different from the first direction and are arranged in a fourth direction intersecting the third direction. The insulating films are each interposed at an intersection point between one of the superconductive lines and one of the conductive lines. The first detection circuit detects a voltage change occurring in the superconductive lines. The second detection circuit detects a current or a voltage generated in the conductive lines when the voltage change occurs.

To prepare a sample for atom probe tomography, a raw sample body having a surface and a region of interest (ROI) to be inspected by APT is provided. Pillars containing the ROI are formed into the surface of the raw sample body via ablation of material of the raw sample body from the surface with an ultra-short pulsed laser. Redeposited ablated material is removed in the region of the formed pillars. The surface of the formed pillars is polished. A preparation device to perform such a preparation method includes a sample handling unit, a pillar forming unit including an ultra-short pulsed laser, a removal unit to remove redeposited ablated material, and a polishing unit. The result is an efficient preparation of robust samples for atom probe tomography. To investigate a region of interest of a sample, the preparation method is performed and then atom probe tomography of the region of interest is performed.

An electron beam application apparatus includes: an optical system configured to irradiate a sample with excitation light; an electron optical system configured to project, onto a camera, a photoelectron image formed by photoelectrons emitted from the sample irradiated with the excitation light; and a control unit. The optical system includes a light source configured to generate the excitation light and a pattern forming unit. The excitation light forms an optical pattern on a surface of the sample when the pattern forming unit is turned on, and the excitation light is emitted to the sample without forming the optical pattern on the surface of the sample when the pattern forming unit is turned off. The control unit adjusts the electron optical system based on feature data of a bright and dark pattern formed by the optical pattern in the photoelectron image obtained by turning on the pattern forming unit.