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Transmission electron microscopy
Transmission electron microscopy (TEM) is a high-resolution imaging technique in which a beam of electrons passes through a thin sample to produce an image. The electron beam is impacted by the sample’s thickness/density, composition and, in some cases, crystallinity. The electrons that are transmitted through the specimen subsequently provide contrast in the resulting image.
TEM is capable of unparalleled resolution due to the small wavelength of the transmitted electrons. Unlike scanning electron microscopy (SEM), which gathers the net intensity of secondary electrons in each point of the scan, TEM resolution is only limited by the wavelength of the individual electron and the quality of the electron optics. This means that transmission electron microscopes can routinely collect sub-nanometer scale (if not atomic-resolution) images.
Scanning transmission electron microscopy
Scanning transmission electron microscopy (STEM) combines the principles of transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Like TEM, STEM requires very thin samples and looks primarily at beam electrons transmitted by the sample. One of STEM’s principal advantages over TEM is that it enables the use of other signals that cannot be spatially correlated in TEM, including characteristic X-rays and electron energy loss spectra (EELS).
Like SEM, STEM scans a very finely focused beam of electrons across the sample in a raster pattern. Interactions between the beam electrons and sample atoms allows for simultaneous acquisition of multi-modal data, which is correlated with beam position to build a virtual image in which the signal level at any location in the sample is represented by the contrast of the image. Its primary advantage over conventional SEM imaging is the improvement in spatial resolution.
With STEM, extremely localized analytical data can be collected for your sample. This includes large-area, high-resolution energy-dispersive X-ray spectroscopy (EDS) maps, probing of oxidation states using EELS, and atomic-resolution imaging of material interfaces.
Cryo-transmission electron microscopes
Cryo-electron microscopy (cryo-EM) describes an increasingly popular group of life sciences techniques including single particle analysis, micro-electron diffraction, and cryo-tomography. Cryo-EM is performed on cryo-transmission electron microscopes (cryo-TEMs), which are specialized TEMs designed to operate at cryogenic temperatures. They typically feature modifications to sample loading, the sample chamber, and the sample stage to maintain the required temperatures and to reduce sample contamination and damage.
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Transmission electron microscopes
Thermo Scientific TEMs feature enhanced imaging and analysis through simplified/automated operation, offering higher data quality and faster acquisition times. They also combine outstanding high-resolution STEM imaging with unparalleled advances in EDS signal detection for compositional mapping and 3D chemical characterization with the Thermo Scientific Dual-X, Super-X, and Ultra-X EDS Detectors. Thermo Scientific TEM platforms are suited for multi-user and multi-discipline environments, combining multiple applications in a single system.
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Nanoscale Materials Characterization
Understanding the nanoscale characteristics of materials is the first step in creating the next generation of lighter, stronger, and more energy efficient solutions. With our electron microscopy solutions, we help you simplify this complex material journey and accelerate your nanoscale materials research. Nanoscale workflow is a journey of material from bulk to nanometer scales using our DualBeam FIB-SEM for sample preparation and Transmission Electron Microscopes for material analysis.
Electron microscopy learning center
Explore electron microscopy resources and reference materials for microscopy novices, experts, and everyone in between. The electron microscopy learning center provides a variety of informational and educational resources on electron microscopy for students, educators, or anyone who simply wants to learn more about this fascinating technology.
High-resolution drift-corrected-frame-integration (DCFI) STEM image of an aluminum-zirconium alloy, collected on the Talos STEM.
Large area, high-resolution EDS mapping of gold-nickel nanoparticles, performed on the Talos STEM platform and acquired in less than 1 minute.
Cadmium sulfide sample, mostly used for optical applications, analyzed with side-entry EDS on the Talos STEM platform.
Gallium arsenide (GaAs) sample imaged with the Spectra STEM. Sample prepared with an oxygen ion beam on the Helios Hydra DualBeam.
STEM image of a metal cross section prepared with a focused ion beam, clearly revealing precipitates (left box) and dislocations (right box). Image width ~10 μm.
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High-resolution drift-corrected-frame-integration (DCFI) STEM image of an aluminum-zirconium alloy, collected on the Talos STEM.
Large area, high-resolution EDS mapping of gold-nickel nanoparticles, performed on the Talos STEM platform and acquired in less than 1 minute.
Cadmium sulfide sample, mostly used for optical applications, analyzed with side-entry EDS on the Talos STEM platform.
Gallium arsenide (GaAs) sample imaged with the Spectra STEM. Sample prepared with an oxygen ion beam on the Helios Hydra DualBeam.
STEM image of a metal cross section prepared with a focused ion beam, clearly revealing precipitates (left box) and dislocations (right box). Image width ~10 μm.
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Electron microscopy services
To ensure optimal system performance, we provide you access to a world-class network of field service experts, technical support, and certified spare parts.
Electron microscopy support and resources
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