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Abstract
By combining high-resolution electron microscopy and atomistic simulations, the atomic structures of several interfaces, {5 1 0}, {2 3 0} and {8 1 0}/{7 4 0}, in germanium and in silicon Σ = 13 [0 0 1] tilt grain boundaries (TGBs) are studied using bicrystals prepared in two different ways from the melt. The interfaces are characterized by either transmission electron microscopy or scanning transmission electron microscopy (STEM). The Si TGB shows only one interface, {1 5 0} with one interfacial structure. The Ge TGB contains many facets. In Ge, observations performed in two perpendicular directions, [0 0 1] and [ 5 0], confirm that the {5 1 0} interface has two different structures. One structure, called M-structure, is periodic along [0 0 1] and has tetracoordinated atoms. The other structure, called U-structure, is more peculiar as it contains a fixed part surrounding a variable complex core. High-resolution STEM, realised in modern microscopes equipped with a probe Cs-corrector, is a very effective technique for structure determination of grain boundaries (GBs). However, current limitations for high-resolution study of GBs are the structural changes under the electron beam and the limited number of crystallographic axes suitable for atomic-resolution imaging. The structures of GB atomistic models can be ordered according to their calculated energies. It appears that energies calculated using empirical potentials, like Tersoff or Stillinger-Weber potentials, do not give the same classification as ab initio calculations and cannot be used to determine the structure of lowest energy. This structure is the M-structure, the structure observed in the Si bicrystal.
Acknowledgements
This paper is in commemoration of the years between 1985–2004 when Jany Thibault-Pénisson, at that time her name was Jany Thibault, was a researcher at CEA-Grenoble. Substantial parts of electron microscopy described here were carried out using the JEOL 4000EX installed at CEA-Grenoble, which was a wonderful microscope. One of us acknowledges the contribution of Alain Bourret for starting the research project that has led to this work. Models in Figure have been drawn using the free V_Sim software available at Citation[29]. We thank Sylvie Lartigue for reading and correcting this paper, together with the anonymous referees and the editors of this special issue.