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In a crystal , a lattice point may be the seat of more than one atom,
and the arrangement of atoms may have a higher degree of symmetry than the
lattice. |
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In Bravais lattices, which are not necessarily the
primitive lattices of a crystal, this feature expresses itself in the fact that
lattice planes that do not contain lattice
points of the elementary lattice, may still
contain atoms. |
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Let's illustrate this somewhat abstract concept
with the familiar fcc and bcc Bravais lattice with an atom on
every lattice point |
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Cubic primitive
lattice:
Atoms are found on all {100} planes
and on every second {200} plane. The
set of {100} and {200} planes
is shown on the left and right of the drawing, respectively |
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Cubic face-centered
lattice:
Atoms on all {100} planes and on
all {200} plane with the same basic
arrangement, just shifted by a/2<010>
or a/2<001>. |
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Cubic
body-centered lattice:
Atoms on all {100} planes and on
all {200} plane with the same basic
arrangement, just shifted by a/2<011>. |
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In terms of defects, this feature
allowed for
stacking faults in the crystals, which could not meaningfully exist just in
the lattice. |
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Well, the
CSL lattice and the
DSC lattice are
lattices, after all. But physical reality
still rests with the atoms. This may have somewhat exotic consequences. |
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The DSC lattice is a lattice that contains
both lattices of the two crystals forming a CSL boundary as subsets. All
atoms sitting on a lattice point of the
crystal lattices therefore are also sitting on a lattice point of the DSC lattice |
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However, atoms not sitting on lattice points of the crystal
lattices, may also not sit on lattice
points of the DSC lattice. In analogy to the example above, there might
be some additional symmetries hidden in the DSC lattice if we consider
all atoms forming the crystals and their positions in the DSC lattice.
In particular, the stacking of planes of the DSC populated with atoms
may allow stacking faults in
the DSC lattice, too, inextricably linked to
partial dislocations in
the DSC lattice. |
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Since reality is (almost) always stranger than
fiction, you should expect that this will
happen - look out for stacking faults in the DSC lattice, and, as a
corollary, DSC dislocation split into partial dislocations in the
DSC lattice. |
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However, these defects in defects in defects may
not be easy to find. Burgers vectors in the DSC lattice tend to be small
which makes the contrast in TEM investigations (the only method with a
chance at detecting this) rather weak. Partial DSC lattice dislocations
would be even harder to see. |
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Moreover, the distance between secondary
dislocations in the typical networks usually encountered, is mostly very small
- there is not much room for splitting! Only in boundaries very close to a
CSL orientation with roomy networks this effect may occur. |
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So there is a good chance that you either never
will see this or, if you see it, you may not recognize what you see. |
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You may even, and with good justification, be of
the opinion that one shouldn't even look, because this topic is almost esoteric
and is completely useless knowledge. |
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But some researchers did look and recognize - see below. Just for the
hell of it, below the head of the article is reproduced as it appeared in
"Phil. Mag."; i.e the Philosophical Magazine, which since its
foundation in 1798 (which means it is one of the oldest science journals
around) evolved into one of the major scientific journals covering TEM
work in general and grain boundary stuff in particular. |
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Here are two pictures of what they found. |
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The left hand picture shows a dislocation network
which is very unusual - nothing like it has ever been observed before with
regular or DSC lattice dislocations. The right hand picture shows the
same network, imaged under different diffraction conditions; the stacking
faults in the DSC lattice are visible. |
© H. Föll
5.4.1 Partial Dislocations and Stacking Faults 
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