Nanoscopy and TEM

The Transmission Electron Microscope (TEM) operates with an electron beam, which observes very thin specimens (~150 nm). Electrons are brought into focus by an electro-magnetic lens and the image is observed on a fluorescent screen, a photographic plate or by means of a CCD camera.

Electrons are accelerated by a potential of the order of hundreds of KV and have wavelengths of about 0.2nm, much smaller than that of a photon (~ 400nm).

The resolving power, of the same order of the incident radiation’s wavelength, is limited by the aberrations of the electro-magnetic lenses.

Technical focus

We use Transmission Electron Microscopy (TEM) to characterize materials and have followed the evolution of this technology’s performance.

Currently, our technical equipment consists of JEOL 3200FS-HR a 300kV TEM, equipped with:

• A field emission gun
• An in-column energy filter for electron energy loss spectrometry and energy-filtered imaging
• A high angle annular dark field detector for STEM Z-contrast imaging
• Energy-dispersive x-ray microanalysis.

It combines high resolution and 0-loss sample imaging with analytical performance: images can be recorded using a 2k x 2k CCD camera. The instrument is used primarily for studying the microstructure, dislocations, crystallography and chemistry of materials (spectra, line scans, maps)

The JEOL 3200FS-HR features:

• Accelerating voltage: 300 kV
• Electron gun: field emission
• Resolution (point to point): 0.19nm
• Spot size: 0.4nm
• Single & double tilt be specimens holder
• In column energy filter (EF-TEM, EELS)
• HAADF
• XEDS
• SADP – NBED – CBED
• Imaging: fluorescent screen, film plate and on axis CCD camera (2k x 2k).

Deliverables

Microstructure analysis

This kind of analysis makes it possible to quantitatively assess the effects of thermal and thermo-mechanical treatments on the morphology and spatial arrangement of the most significant nanostructural constituents:

• Chemical composition
• Size and shape
• Position with respect to the grain dislocation density and mechanical deformation status.

Crystallographic analysis

The knowledge of Crystallography allows for the identification of phases through the analysis of electronic diffraction patterns, interpreted utilizing a software designed by CSM.

“High-resolution” microscopy

The high-resolution mode enables us to observe the atomic planes disposition and spacing and to underline the defects of the crystal lattice.

EFTEM – Energy-Filtered TEM

The sophisticated electromagnetic filter gives us information about the chemical composition of the constituent elements of the microstructure.

Energy Dispersive Spectrometer (XEDS)

The EDS dispersive spectrometer (XEDS) qualitatively and quantitatively carries out the chemical composition analysis of a specific point of the sample with a spatial resolution of a few nanometres.

Assessment of particles' size distribution

The automatic image analysis software calculates the geometrical parameters of the particles (area, diameter, form factor, perimeter, etc.) present in a specific field, which allows us to perform various statistical analyses.

Sample preparation laboratory

The preparation of samples plays a crucial role in the success of TEM observations. We offer you a wide experience in the preparation of non-organic samples, with particular regard to metals and alloys.