Atom probe

Visualisation of data obtained from an atom probe, each point represents a reconstructed atom position from detected evaporated ions.

The atom probe was introduced at the 14th Field Emission Symposium in 1967 by Erwin Wilhelm Müller and J. A. Panitz. It combined a field ion microscope with a mass spectrometer having a single particle detection capability and, for the first time, an instrument could “... determine the nature of one single atom seen on a metal surface and selected from neighboring atoms at the discretion of the observer”.[1]

Atom probes are unlike conventional optical or electron microscopes, in that the magnification effect comes from the magnification provided by a highly curved electric field, rather than by the manipulation of radiation paths. The method is destructive in nature removing ions from a sample surface in order to image and identify them, generating magnifications sufficient to observe individual atoms as they are removed from the sample surface. Through coupling of this magnification method with time of flight mass spectrometry, ions evaporated by application of electric pulses can have their mass-to-charge ratio computed.[2]

Through successive evaporation of material, layers of atoms are removed from a specimen, allowing for probing not only of the surface, but also through the material itself.[3] Computer methods are used to rebuild a three-dimensional view of the sample, prior to it being evaporated, providing atomic scale information on the structure of a sample, as well as providing the type atomic species information.[4] The instrument allows the three-dimensional reconstruction of up to billions of atoms from a sharp tip (corresponding to specimen volumes of 10,000-10,000,000 nm3).

  1. ^ Müller, Erwin W.; Panitz, John A.; McLane, S. Brooks (1968). "The Atom-Probe Field Ion Microscope". Review of Scientific Instruments. 39 (1): 83–86. Bibcode:1968RScI...39...83M. doi:10.1063/1.1683116. ISSN 0034-6748.
  2. ^ Müller, E. W. (1970). "The Atom-Probe Field Ion Microscope". Naturwissenschaften. 5: 222–230. {{cite journal}}: Cite journal requires |journal= (help)
  3. ^ Miller, M; Smith, G. (1989). Atom Probe Microanalysis: Principles and Applications to Materials Problems. Materials Research Society. ISBN 978-0-931837-99-9.
  4. ^ Miller, M. (2000). Atom Probe Tomography: Analysis at the Atomic Level. Kluwer Academic/Plenum Publishers. ISBN 978-0-306-46415-7.