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Microscopy characterization

It is well know (1), that hard spheres canequally be close packed into a face centred cubic (fcc), a hexagonal close packed (hcp) orany mixture thereof. From gravitational energy considerations, all of them are equally probable. This fact is of crucial importance in PBG technology, since the fcc structure has been shown to present a full gap, provided an appropriate refractive index contrast is achieved. In this sense, a sophisticated method was devised in order to force the colloidal crystallisation in the fcc phase. Only recently, it has been shown both theoretically, by using computer simulations (2), and experimentally (3) that fcc order is the most stable phase. In Fig. 1 one can see a low magnification SEM image of internal facets (observable after cleavage) of an artificial opal made by natural sedimentation as described above. The triangular order corresponding to a crystalline plane belonging to the {111} family (lower part of the image) can be seen. Also, square, rectangular and  triangular arrangements of spheres, belonging to {100}, {110} and {111} sets of planes, can be seen at the cleft edge (upper part of the image).

In Fig. 2 one can see a computer
simulation of an fcc order (central image) surrounded by SEM images of actual
crystallographic planes. All these planes can only be present in an fcc stacking thus
demonstrating the statement. The results reported, so far, involve opals in which the
interparticle voids are filled with air. We call those samples “bare opals”.
Bare as-grown opals are solid but present a low mechanical stability. To improve it, a
sintering process can be performed.

Want to see more pictures?

1.- C. Kittel. 1968. ‘Introduction to
Solid State Physics’, Third Edition, John Wiley.

2.- L.V. Woodcock. 1997. Nature 385,
141.

3.- H. Míguez, F. Meseguer C. López, A.
Mifsud, J. S. Moya, and L. Vázquez. 1997. Langmuir. 13, 6009.