A charged particle beam apparatus includes a sample stage on which a sample is mounted, a control device that controls to drive the sample stage, a linear scale that detects a position of the sample stage, laser position detection means for detecting the position of the sample stage, an optical microscope that observes the sample mounted on the sample stage, and a barrel that irradiates the sample mounted on the sample stage with an electron beam, and generates a secondary electron. Image data of a first correction sample mounted on the sample stage is acquired by the optical microscope, and position data of the sample stage is detected by the laser position detection means. The sample stage is positioned with respect to the barrel based on the image data acquired by the optical microscope and the position data of the sample stage detected by the laser position detection means.

A positioning system for an electron microscope includes a first carriage comprising a holder for holding a workpiece and a second carriage. The first carriage being coupled to one or more first drive units configured to position the workpiece along first, second, and third axes, and along a first tilt axis. The second carriage housing the one or more first drive units and being coupled to one or more second drive units configured to position the workpiece along a second tilt axis.

Systems, devices, and methods for performing a non-contact electrical measurement (NCEM) on a NCEM-enabled cell included in a NCEM-enabled cell vehicle may be configured to perform NCEMs while the NCEM-enabled cell vehicle is moving. The movement may be due to vibrations in the system and/or movement of a movable stage on which the NCEM-enabled cell vehicle is positioned. Position information for an electron beam column producing the electron beam performing the NCEMs and/or for the moving stage may be used to align the electron beam with targets on the NCEM-enabled cell vehicle while it is moving.

Cryo compatible sample grids having multi-modal cryo-EM compatible GUIDs, according to the present disclosure include an outer support structure that defines a region of the grid for holding one or more samples, and a plurality of inner support structures that define a plurality of apertures that are each configured to hold a sample. Cryo compatible sample grids further include a first identifier located on the outer support structure, and a second identifier located within the region of the grid for holding the one or more samples. The first identifier is readable with an optical detector, while the second identifier is readable with an electron detector (e.g., within an electron microscope). Specifically, the second identifier is readable with an electron detector when one or more teeth and/or holes that comprise the second identifier are filled with ice from a vitrification process.

An observation method includes: preparing a specimen including, as a mark a plurality of metal particles in which localized surface plasmon resonance is excited by irradiation with light; acquiring an optical microscope image by photographing the specimen with an optical microscope; acquiring an electron microscope image by photographing the specimen with an electron microscope; acquiring information of the positions and the colors of the plurality of metal particles in the optical microscope image; acquiring information of the positions and the particle diameters of the plurality of metal particles in the electron microscope image; and determining information for associating the optical microscope image and the electron microscope image based on the information of the positions and the colors of the plurality of metal particles acquired from the optical microscope image, and the information of the positions and the particle diameters of the plurality of metal particles acquired from the electron microscope image.

An object of the present disclosure is to provide a charged particle beam device that can suppress an influence to a device generated according to the preliminary exhaust. In order to achieve the object, suggested is a charged particle beam device including a vacuum sample chamber that maintains an atmosphere around a sample to be irradiated with a charged particle beam in a vacuum state; and a preliminary exhaust chamber to which a vacuum pump for vacuuming an atmosphere of the sample introduced into the vacuum sample chamber is connected, in which the vacuum sample chamber is a box-shaped body including a top plate, and a portion between the top plate and a side wall of the box-shaped body positioned below the top plate includes a portion in which the top plate and the side wall are not in contact with each other.

A height measuring device includes a light source that emits light in a direction oblique to a top surface of a specimen, a slit that shapes the light from the light source to form a slit image on the specimen, an imaging element that detects reflected light reflected by the specimen, and an arithmetic unit. The arithmetic unit: identifies a slit image of the reflected light reflected by the top surface of the specimen from among a plurality of slit images based on respective positions of the plurality of slit images on a detection surface of the imaging element; and determines the height of the top surface of the specimen based on the position of the slit image of the reflected light reflected by the top surface of the specimen on the detection surface.

Provided is a stage apparatus that reduces thermal deformation and temperature rise in an upper table on which a sample is mounted and a charged particle beam apparatus including the stage apparatus. The stage apparatus includes: an upper stage that moves an upper table on which a sample is mounted in a first direction; a middle stage that moves a middle table on which the upper stage is mounted in a second direction orthogonal to the first direction; and a lower stage that moves a lower table on which the middle stage is mounted in a third direction orthogonal to the first direction and the second direction. The upper table and the middle table use a material having a smaller thermal expansion coefficient than in a material of the lower table, and the lower table uses a material having higher thermal conductivity than in the material of the upper table and the middle table.

In a charged particle beam apparatus is provided with an optical image capturing apparatus having an angle different from that of a column, a sample may collide with other components when the sample is faced toward the optical image capturing apparatus. The charged particle beam apparatus includes a stage configured to place a sample thereon and to move the sample inside a sample chamber; a column configured to observe the sample by irradiating a charged particle beam on the sample; a first image capturing apparatus configured to observe a surface of the sample irradiated with the charged particle beam from an angle different from that of the column; and a control unit configured to, when observing the sample via the first image capturing apparatus, separate the sample from the column and to tilt the sample through the stage to face toward the first image capturing apparatus.

According to an embodiment, a charged particle beam apparatus includes a stage; a chamber; an emission source of the charged particle beam; an electronic optical system configured to emit the charged particle beam; an optical column including the emission source and the electronic optical system; a charged particle detector configured to detect a position of the charged particle beam; a first actuator configured to provide a frequency vibration to the stage based on a first excitation signal; a second actuator configured to provide a frequency vibration to the optical column based on a second excitation signal; a third actuator configured to provide a frequency vibration to the chamber based on a third excitation signal; and a controller configured to generate the first to third excitation signals.