Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-23T17:01:14.108Z Has data issue: false hasContentIssue false

Application of scanning electron diffraction in the transmission electron microscope for the characterisation of dislocations in minerals

Published online by Cambridge University Press:  30 July 2018

Billy C. Nzogang
Affiliation:
Université de Lille, CNRS, INRA, ENSCL, UMR 8207 – UMET – Unité Matériaux et Transformations, F-59000 Lille, France
Alexandre Mussi
Affiliation:
Université de Lille, CNRS, INRA, ENSCL, UMR 8207 – UMET – Unité Matériaux et Transformations, F-59000 Lille, France
Patrick Cordier*
Affiliation:
Université de Lille, CNRS, INRA, ENSCL, UMR 8207 – UMET – Unité Matériaux et Transformations, F-59000 Lille, France
*
*Author for correspondence: Patrick Cordier, Email: [email protected]

Abstract

We present an application of scanning electron diffraction for the characterisation of crystal defects in olivine, quartz and phase A (a high pressure hydrated phase). In this mode, which takes advantage of the ASTAR™ module from NanoMEGAS, a slightly convergent probe is scanned over the sample with a short acquisition time (a few tens of ms) and the spot patterns are acquired and stored for further post-processing. Originally, orientation maps were constructed from automatic indexing at each probe location. Here we present another application where images are reconstructed from the intensity of diffraction spots, producing either so-called ‘virtual’ bright- or dark-field images. We show that these images present all the characteristics of contrast (perfect crystal or defects) of conventional transmission electron microscopy images. Data are acquired with a very short time per probe location (a few tens of milliseconds), this technique appears very attractive for the characterisation of beam-sensitive materials. However, as the acquisition is done at a given orientation, fine tuning of the diffraction conditions at a given location for each reflection is not possible. This might present a difficulty for some precise, quantitative contrast analysis.

Type
Article
Copyright
Copyright © Mineralogical Society of Great Britain and Ireland 2018 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Associate Editor: Giancarlo Della Ventura

References

Barnard, J.S., Sharp, J., Tong, J.R. and Midgley, P.A. (2006 a) High-resolution three-dimensional imaging of dislocations. Science, 313, 319.Google Scholar
Barnard, JS, Sharp, J, Tong, JR and Midgley, PA (2006 b) Three dimensional analysis of dislocation networks in GaN using weak-beam dark-field electron tomography. Philosophical Magazine, 86, 49014922.Google Scholar
Barnard, J.S., Eggeman, A.S., Sharp, J., White, T.A. and Midgley, P.A. (2010) Dislocation electron tomography and precession electron diffraction – minimising the effects of dynamical interactions in real and reciprocal space. Philosophical Magazine, 90, 47114730.Google Scholar
Cockayne, D.J.H., Ray, I.L.F. and Whelan, M.J. (1969) Investigation of dislocation strain fields using weak beams. Philosophical Magazine, 20, 12651270.Google Scholar
Cordier, P., Boulogne, B. and Doukhan, J.C. (1988) Water precipitation and diffusion in wet quartz and wet berlinite AlPO4. Bulletin de Minéralogie, 111, 113137Google Scholar
Cordier, P., Morniroli, J.P. and Cherns, D. (1995) Characterization of crystal defects in quartz by large-angle convergent-beam electron diffraction. Philosophical Magazine, 72, 14211430.Google Scholar
Doukhan, J.C. (1995) Lattice defects and mechanical behaviour of quartz SiO2. Journal de Physique III, 5, 18091832.Google Scholar
Gouriet, K., Hilairet, N., Amiguet, E., Bolfan-Casanova, N., Wang, J., Reynard, B. and Cordier, P. (2015) Plasticity of the dense hydrous magnesium silicate Phase A at subduction zones conditions. Physics of the Earth and Planetary Interiors, 248, 111.Google Scholar
Hirsch, P.B., Horne, R.W. and Whelan, M.J. (1956) Direct observation of the arrangement and motion of dislocations in aluminium. Philosophical Magazine, 1, 677684.Google Scholar
Hirsch, P.B., Howie, A. and Whelan, M.J. (1960) A kinematical theory of diffraction contrast of electron transmission microscope images of dislocations and other defects. Philosophical Transactions of the Royal Society, A252, 499529.Google Scholar
Horiuchi, H., Morimoto, N., Yamamoto, K. and Akimoto, S.I. (1979) Crystal-structure of 2Mg2SiO4·3Mg(OH)2, a new high-pressure structure type. American Minereralogist, 64, 593598.Google Scholar
Ishida, Y., Ishida, H., Kohra, K. and Ichinose, H. (1980) Determination of the Burgers vector of a dislocation by weak-beam imaging in a HVEM. Philosophical Magazine, 42, 453462.Google Scholar
Kiss, A.K., Rauch, E.F. and Lábár, J.L. (2016) Highlighting material structure with transmission electron diffraction correlation coefficient maps. Ultramicroscopy, 163, 3137.Google Scholar
McLaren, A.C. and Phakey, P.P. (1965 a) Dislocations in quartz observed by Transmission Electron Microscopy. Journal of Applied Physics, 36, 32443246.Google Scholar
McLaren, A.C. and Phakey, P.P. (1965 b) A transmission electron microscope study of amethyst and citrine. Australian Journal of Physics, 18, 135141.Google Scholar
McLaren, A.C. and Phakey, P.P. (1966) Electron microscope study of Brazil twin boundaries in amethyst quartz. Physica Status Solidi, 13, 413422.Google Scholar
McLaren, A.C. and Phakey, P.P. (1969) Diffraction contrast from Dauphiné twin boundaries in quartz. Physica Status Solidi, 31, 723737.Google Scholar
Mussi, A., Cordier, P. and Frost, D.J. (2012) Crystal defects in dense hydrous magnesium silicate phase A deformed at high pressure: characterization by transmission electron microscopy. European Journal of Mineralogy, 24, 429438.Google Scholar
Mussi, A., Cordier, P., Demouchy, S. and Vanmansart, C. (2014) Characterization of the glide planes of the [001] screw dislocations in olivine using electron tomography. Physics and Chemistry of Minerals, 41, 537545.Google Scholar
Orowan, E. (1934) Zur Kristallplastizität. III. Über den Mechanismus des Gleitvorganges [To crystal plasticity III. About the mechanism of glide]. Zeitschrift für Physik, 89, 634.Google Scholar
Polanyi, M. (1934) Über eine Art Gitterstörung, die einen Kristall plastisch machen könnte [About a kind of lattice distortion that could render a crystal plastic]. Zeitschrift für Physik, 89, 660.Google Scholar
Poli, S. and Schmidt, M. (1997) The high-pressure stability of hydrous phases in orogenic belts: an experimental approach on eclogite-forming processes. Tectonophysics, 273, 169184Google Scholar
Rauch, E.F. and Dupuy, L. (2005) Rapid spot diffraction patterns identification through template matching, Archives of Metallurgy and Materials, 50, 8799.Google Scholar
Rauch, E.F. and Véron, M. (2014 a) Analyzing dislocations with virtual dark field images reconstructed from electron diffraction patterns. Microscopy and Microanalysis, 20(Suppl 3), 14561457.Google Scholar
Rauch, E.F. and Véron, M. (2014 b) Automated crystal orientation and phase mapping in TEM. Materials Characterization, 98, 19.Google Scholar
Rühle, M, Wilkens, M. and Essmann, U. (1965) Zur deutung des elecktronenmikroskopischen kontrasterscheinungen an fehlstellenagglomeraten in neutronenbestrahltem kupfer. Physica Status Solidi, 11, 819829.Google Scholar
Taylor, G.I. (1934) The mechanisms of plastic deformation of crystals. Part I – Theoretical; Part II – Comparison with observation. Proceedings Royal Society, Series A, 145, 362415.Google Scholar
Thieme, M., Demouchy, S., Mainprice, D., Barou, F. and Cordier, P. (2018) Stress evolution and associated microstructure during transient creep of olivine at 1000–1200°C. Physics of the Earth and Planetary Interiors, 278, 3446.Google Scholar
Trépied, L. and Doukhan, J.C. (1978) Dissociated ‘a’ dislocations in quartz. Journal of Materials Science, 13, 492498.Google Scholar
Van Landuyt, J., Gevers, R. and Amelinckx, S. (1964) Fringe patterns at anti-phase boundaries with α = π observed in the electron microscope. Physica Status Solidi, 7, 519546.Google Scholar
Van Landuyt, J., Gevers, R. and Amelinckx, S. (1965) Dynamical theory of the images of microtwins as observed in the electron microscope I. Overlapping twins. Physica Status Solidi, 9, 135165.Google Scholar
Supplementary material: File

Nzogang et al. supplementary material

Nzogang et al. supplementary material 1

Download Nzogang et al. supplementary material(File)
File 12.5 MB