SuperSTEM - the UK aberration-corrected STEM facility
Lead Research Organisation:
University of Glasgow
Department Name: School of Physics and Astronomy
Abstract
Electron microscopes allow scientists to see and analyse solid materials on the atomic scale. Conventional electron microscopes suffer from aberrations which limit their ability to resolve fine detail. These aberrations can now be corrected, just as defects in human vision can be corrected by glasses. The SuperSTEM project has involved the development and testing of two special aberration-corrected microscopes, the second of which is being installed at the end of 2005. These microscopes enable scientists to determine the nature and position of specific atoms and small groups of atoms in materials such as semiconductor devices, catalysts and environmental particulates. This proposal is to enable the two SuperSTEM microscopes to produce experimental results for applications a range of fields of scientific and technological importance and to give UK researchers and students world-leading expertise in analytical techniques.Among the things we propose to do are:* Develop smart ways of collecting information, so that we can look at a single column of atoms for a very long time, even if it is moving slightly.* Develop new ways of simulating what atoms and crystal defects should look like in an aberration-corrected STEM, so that we can interpret what we see by comparison with predicted images.* Seek collaborators to develop the understanding of the energy loss process as the probe becomes smaller than the atom spacing * Develop a new type of x-ray detector so that we can analyse at the atomic scale using either or both x-rays and energy loss spectrometers, whichever is most appropriate.* Determine where dopants atoms are in small semiconductor device structures which rely on only a few atoms to operate.* Analyse the atoms which are most significant to the operation or effect of catalysts, strong materials, pollutant particles, quantum dots, magnetic nanoparticles and iron in the liver.* Train the next generation of scientists who will be able to exploit this excellent technology for the benefit of mankind.
Organisations
People |
ORCID iD |
Alan Craven (Principal Investigator) |
Publications
Azough F
(2016)
Tungsten Bronze Barium Neodymium Titanate (Ba(6-3n)Nd(8+2n)Ti(18)O(54)): An Intrinsic Nanostructured Material and Its Defect Distribution.
in Inorganic chemistry
Bosman M
(2007)
Two-dimensional mapping of chemical information at atomic resolution.
in Physical review letters
Craven A
(2011)
Nanoanalysis of a sub-nanometre reaction layer in a metal inserted high-k gate stack
in Microelectronic Engineering
Gass MH
(2008)
Free-standing graphene at atomic resolution.
in Nature nanotechnology
Hansen LP
(2011)
Atomic-scale edge structures on industrial-style MoS2 nanocatalysts.
in Angewandte Chemie (International ed. in English)
Kovács A
(2013)
Characterization of Fe-N nanocrystals and nitrogen-containing inclusions in (Ga,Fe)N thin films using transmission electron microscopy
in Journal of Applied Physics
Livi KJ
(2013)
Atomic-scale surface roughness of rutile and implications for organic molecule adsorption.
in Langmuir : the ACS journal of surfaces and colloids
MacLaren I
(2012)
Novel Nanorod Precipitate Formation in Neodymium and Titanium Codoped Bismuth Ferrite
in Advanced Functional Materials
Mendis BG
(2011)
Characterising the surface and interior chemistry of core-shell nanoparticles using scanning transmission electron microscopy.
in Ultramicroscopy