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Posted: July 3, 2008

Atomic scale microscopy goes commercial

(Nanowerk News) The state-of-the-art technique for seeing atoms – transmission electron microscopy (TEM) – will become an important tool for chemical analysis over the next decade as instrument manufacturers commercialise advances pioneered in laboratories, researchers heard at the Microscience 2008 conference in London, UK.
TEM determines atomic structures from the way beams of accelerated electrons scatter when shot through thin wafers of material. Thanks to high-powered computers, sophisticated lenses which remove optical aberrations, and brighter light sources, the best commercial microscopes can now achieve sub-angstrom resolution. Even non-heavy elements, which only weakly scatter electrons, can be imaged at high resolution. A collaboration at the Transmission electron aberration-corrected microscope (Team) project at Lawrence Berkeley National Laboratory in California, US, for example, has published a sub-angstrom resolution image of the lattice of graphene (a one-atom thick sheet of carbon) ("Direct Imaging of Lattice Atoms and Topological Defects in Graphene Membranes"). Co-author Chris Kisielowski says the researchers were also able to spot adsorbates writhing around on the graphene surface. 'In principle, we can now detect all the elements of the periodic table - even hydrogen,' he says.
graphene sheets on a perforated carbon film
An optical micrograph (a) and a low-magnification TEM image (b) of graphene sheets on the perforated carbon film. The high-resolution TEM image (c) shows adsorbates (the structures near the edge of the image) and a hole on the left (Image: Nano Letters)
With resolution increased to this degree, chemical applications of TEM are becoming increasingly important. 'In terms of pure resolution I think we are reaching a limit: simply because there will need to be a lot of money invested to commercialise instruments below 0.5 Angstroms [the current record],' says Knut Urban, one of the pioneers of high-resolution electron microscopy, who is now head of the Institute for solid-state research, at the research centre Julich, Germany. But because TEM, in combination with other techniques, can determine the chemical identity of atoms, research labs are adopting it to explore structures of semiconductors, catalysts, fuel cells and other nanostructures. For one of many examples, a team led by David Muller at Cornell University, US, used a commercial instrument made by the Seattle-based company Nion to take fast atomic-resolution maps of a multilayered perovskite, determining changes in the bonding of titanium, manganese and lanthanum atoms in different chemical locations ("Atomic-Scale Chemical Imaging of Composition and Bonding by Aberration-Corrected Microscopy").
It's also possible to follow the behaviour of catalyst surfaces as they are smothered in reactant gases, or as temperatures and pressures change to reflect more life-like conditions. 'In the 1980s this so-called environmental TEM [ETEM] was developed via special research projects - now it's become a standard configuration for a wider audience,' says Bert Freitag, of Oregon-based company FEI, who launched an ETEM version of their Titan microscope range - costing some 3 to 4 million euros - at the conference. Using a non-commercial version of this instrument, a collaboration of UK, Danish and US scientists recently managed to image in detail the creation of silicon nanowires aided by palladium catalyst particles when exposed to silane gas ("Ledge-flow-controlled catalyst interface dynamics during Si nanowire growth").
Interest in this kind of analysis is not restricted to the academic laboratory. 'We now have a contract with BASF, for example, on the application of ultra-high resolution techniques to practical problems of a chemical company,' says Urban. Researchers working with semiconductors and catalysts can use TEM to measure even picometre shifts in atomic positions - particularly important in areas where regular lattices deviate or may be doped with interloper atoms, such as at grain boundaries and interfaces.
This year has already seen two advanced TEMs inaugurated - the 'supercentre' scanning TEM at Daresbury, UK, and the US Team project which will open to outside users in October. With instruments expected to get cheaper and more user-friendly, the only thing limiting wider use is expertise and training, says Urban. 'Within the next decade this technique will be very widely applied,' he says.
Source: Reprinted with permission from Chemistry World (Richard Van Noorden)