An examination container includes a main body, a cover and a carrier stage. The main body has an accommodating trough for holding a sample. The cover is detachably connected to the main body to close the accommodating trough. The cover has a first through-hole penetrating through an outer surface and an inner surface of the cover, and includes a membrane arranging on the inner surface of the cover. The membrane has a second through-hole opposite to the first through-hole for passing an electron beam through the first through hole and the second through hole. The carrier stage is installed in a position corresponding to the second through-hole. The carrier stage is detachably arranged in the accommodating trough for a variety of examination purposes. An electron microscope using the abovementioned examination container is also disclosed.

An apparatus for observing a sample using a charged particle beam includes an ion beam column configured to generate and direct an ion beam, an electron beam column configured to generate and direct an electron beam, a vacuum chamber for housing the sample, and a probe positioned in the vacuum chamber. The probe is configured to provide electrical connection between the sample and a power supply.

The present disclosure relates to in situ transmission electron microscope (TEM) holders with improved stability and electrical sensitivity. The holders feature a front bearing seal and a rear bearing seal which allow the holders to achieve high sensitivity, high stability, large range of motion and high vacuum isolation. The bearings use a PEEK insulating disk as a pivot point for translation and tilting motion, and use O-rings to dampen vibrations, provide electrical and vacuum insulation, and to set a grabbing force between the bearing and the probe.

A laser beam illumination equipment has a laser beam generation section and a mirror unit. An image generation section has a camera and a camera controller. A laser beam illumination control section sets a pulse period of a laser beam to the same period as an exposure period of the camera. With this configuration, a state change of a specimen can be set uniform over exposure durations. A pulse train of the laser beam may be generated based on a synchronization signal which is output from the camera controller.

Provided is a scanning electron microscope. The scanning electron microscope is capable of removing a charge generated on a side wall of a deep hole or groove, and inspects and measures a bottom portion of the deep hole or groove with high accuracy. Therefore, in the scanning electron microscope that includes an electron source 201 that emits a primary electron, a sample stage 213 on which a sample is placed, a deflector 207 that causes the sample to be scanned with the primary electron, an objective lens 203 that focuses the primary electron on the sample, and a detector 206 that detects a secondary electron generated by irradiating the sample with the primary electron, a potential applied to the sample stage is controlled to have a negative polarity with respect to a potential applied to the objective lens during a first period in which the sample is irradiated with the primary electron, and the potential applied to the sample stage is controlled to have a positive polarity with respect to the potential applied to the objective lens during a second period in which the sample is not irradiated with the primary electron.

An apparatus is disclosed for use in a charged particle instrument which defines an inner volume therein. The apparatus comprises an adaptor (22) having a first portion adapted for attachment to a part (20) of a gas injection system (18) of a charged particle instrument which is located within an inner volume of such an instrument; and a second portion arranged to receive a tool (24) adapted for interaction with a sample (14) located in the inner volume of such an instrument.

An apparatus and a method for measuring and monitoring the properties of a fluid, for example, pressure, temperature, and chemical properties, within a sample holder for an electron microscope. The apparatus includes at least one fiber optic sensor used for measuring temperature and/or pressure and/or pH positioned in proximity of the sample.

A method of observing a solid sample (100) with a microscope (300), comprising engaging a rotating portion (110) with a first part (104) of the sample (100), holding a second part (106) of the sample (100), and rotating the rotating portion (110) so as to rotate the first part (104) of the sample (100) relative to the second part (106) of the sample (100).

A double-tilt in-situ nanoindentation platform for TEM (transmission electron microscope) belongs to the field of in-situ characterization of the mechanical property-microstructure relationship of materials at the nano- and atomic scale. The platform is consisted of adhesive area, support beams, bearing beams, sample loading stage and mini indenter. The overall structure of the platform is prepared by semiconductor microfabrication technology. The in-situ nanoindentation experiment can be driven by bimetallic strip, V-shaped electro-thermal beam, piezoelectric ceramics, electrostatic comb or shape memory alloys et. al. The sample is obtained by focused ion beam cutting. The integrated platform can be placed in the narrow space on the front end of the TEM sample holder, giving rise to the condition of double-axis tilt. The driving device drives the mini indenter to carry out in-situ nanoindentation, in-situ compression and in-situ bending and the like of the materials in TEM. The deformation process of material can be in-situ observed in sub angstrom, atomic and nano scale to study the deformation mechanism of material, which can further reveal the relationship of microstructure-mechanical properties of the material.

An electrostatic particle beam combiner for creating a single source combining the properties of two particle beams which form a high brightness source of a selected mixture of ions of varying element types and energies. An electrostatic spherical lens is arranged to bend a low energy second particle beam along a circular path and thereafter to impinge on a surface of a sample, e.g., within a transmission electron microscope. A beam of high energy is injected into the electrostatic spherical lens through an aperture in the outer shell and steered by two spaced apart electrostatic deflectors so that the angle of entry and the point of entry can be independently adjusted so that the high energy beam leaves the spherical lens along a path which is coaxial and coincident with the second particle beam of low energy.