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Phase diagrams are the mainstay of materials
science and technology. They may be seen as a map in temperature - composition space that shows
the particular structure with the minimum free enthalpy at any point of the
"map". |
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If we take the
formula for
the equilibrium concentration of self-interstitials to also describe the
equilibrium concentration of extrinsic interstitial atoms if we replace the
formation enthalpy by a corresponding property (lets call it solubility enthalpy), the resulting diagram of the
equilibrium concentration over temperature can be interpreted as part of a
phase diagram. |
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All we have to do is to switch the axes from the normal
representation concentration vs.
temperature to temperature vs.
concentration: |
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We now have a diagram for the composition of
material A (the matrix) with material B (the extrinsic
interstitial) for small concentrations of B. |
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The red line denotes the limit of solubility of B in
A; it corresponds to the equilibrium concentration. |
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In the yellow or blue areas, the B-interstitials are
undersaturated or supersaturated, respectively. We must expect that
something new is going to happen in the supersaturated region, e.g. the
precipitation of some AxBy compound, or a phase
separation of A and B. |
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On the other end of the composition axis, things would be much
the same, only that now A is the interstitial in B. The
equilibrium line and the melting point would be different too, of course. |
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The phase diagram Pb - Sn (familiar
solder) provides a real example: |
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Pure lead and lead with Sn interstitials
has a fcc lattice; we call this the a-phase; pure Sn and Sn with
Pb interstitials is tetragonal, we call this the b-phase. |
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In the supersaturated region something new has happened
ndeed, we have an eutectic phase separation
and a mixture of a and b. |
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In the high temperature regime, we have something new, too:
Mixtures of liquid (L) and solid phases |
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Be that as it may (and it can be much more
complicated), the essential points are |
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The system always goes for the minimum free enthalpy, and this
minimum could be calculated in principle following the same, albeit much more
involved line of reasoning we employed for equilibrium concentrations of point
defects. |
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The (experimentally determined) phase diagrams are maps of the
particular minimum free enthalpy configuration out of many possible
arrangements for a given composition and temperature. |
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Changing the temperature or the composition of a system thus
takes us from one area in the phase diagram to another; the boundaries we have
to cross give us an idea of what has to happen kinetically. |
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© H. Föll
2.2.1 Extrinsic Point Defects and Agglomerates 
To index