 |
We consider a complex of one vacancy and one foreign atom (a Johnson complex)
in thermodynamic equilibrium. |
|
 |
We start with a number
nF of foreign atoms that is given by external circumstances. Some, but not necessarily all of these
atoms will form a complex with a vacancy. The number of these complexes we call nC. |
|
We can calculate the equilibrium number of Johnson complexes exactly analogous
to the equilibrium number of vacancies by simply defining a formation enthalpy GC and doing the
counting of arrangements and minimization of the free enthalpy procedure. |
|
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This obviously will give us |
|
|
| nC |
= (NC – nC) · exp – |
GC
kT |
|
|
|
|
With NC = number of sites in the crystal where a vacancy could sit
in order to form a Johnson complex. |
|
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We take NC – nC in full generality because
the places already occupied ( = nC) are no longer available, and we do not
assume at this point that nC << NC applies as in the case of vacancies. |
|
NC, of course, is not
the number of atoms of the crystal as in the case of vacancies, but roughly the number
of foreign atoms - after all, only where we have a foreign atom, can we form a complex. |
|
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If we don't look at the situation roughly but in detail,
we need to consider that there are as many possibilities to form a foreign atom - vacancy pair as there are nearest neighbors.
We thus find |
| |
|
|
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z is the coordination number of the lattice considered, i.e. the number of nearest
neighbors. Again we do not neglect the places already taken, i.e. we subtract nC · z
from the total number of places. |
|
If we look at concentrations, we refer the
numbers to the number of lattice atoms N which gives us for the concentration cC
of impurity atom - vacancy complexes |
|
|
cC
cF – cC | = z · exp –
| GC
kT |
|
|
|
We are essentially done. We have the concentration of Johnson complexes as a function
of the concentration of the foreign atoms, the lattice type (defining z) and their formation enthalpy. |
|
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However, we would feel happier, if we could base the equation on material parameters which
we already know - in particular on the equilibrium concentration of vacancies in the given material. |
|
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This needs a closer view on the formation enthalpy of the complex. |
|
As in the case of double vacancies, we may simply assume that there is a binding
enthalpy between a vacancy and a foreign atom (otherwise there would be no driving force to form a complex in the first
place). |
|
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We thus can write for GC |
| |
| GC = GVF – (HC
– T · DSC) |
|
|
|
|
GVF is the free enthalpy of vacancy formation, HC
is the binding enthalpy of a Johnson complex,
and T · DSC is the "association entropy" of the complex, accounting for the entropy change of the crystal
upon the formation of a complex. |
|
Inserting this in the equation above gives for the concentration
of Johnson complexes in terms of vacancy parameters and binding energies: |
| |
cC
cF – cC | = z · exp –
| GVF
kT |
· exp |
HC
kT | · exp |
DSC
k |
| cC | = |
(cF – cC) · cV · z · |
exp |
HC
kT |
· exp |
DSC
k |
| | | |
| | |
| | | = |
c'F · cV · z · |
exp |
HC
kT |
· exp |
DSC
k |
|
|
|
|
We used the familiar equation cV = exp – (GVF/
kT) to get this result. |
|
We abbreviated the difference of the total concentration of foreign atoms and
the concentration of Johnson complexes by c'F; i.e. c'F = (cF
– cC) because this allows a simple interpretation of the equation. |
|
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The point now is to recognize that c'F is nothing but the concentration
of foreign atoms which are still available for a reaction with a vacancy, and that the last equation therefore is nothing
but the mass action law written out for the reaction |
|
|
|
|
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With F = (available) foreign atom; V = vacany, and C = Johnson complex. |
|
Looking closely (= thinking hard) you will notice that we now have a certain inconsistency
in our book keeping: |
|
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We always took into account that Johnson complexes already formed can not
be neglected in counting possibilites, and we always corrected for that by using cF – cC
and so on - but we did not correct for the now more limited possibilities for positioning
a single vacancy. We must ask ourselves if the presence of foreign atoms will change the equilibrium concentration of free
vacancies. |
|
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In other words, while we took the number of available positions for a vacancy in a complex
to be nF · z – nC · z, we implicitly took the number
of available positions for a free vacancy in the crystal to be simply N = number of lattice atoms.
|
|
|
Being more precise, we have to subtract nF · z from N
because nF · z positions are, after all, not available
for free vacancies. We thus have to replace N by N' = N
– nF · z when we consider the number of free vacancies. |
|
|
The concentration of the free vacancies thus becomes cV = (1 –
z · cF) · exp – (GVF/ kT), or exp –
(GVF/ kT) = cV / (1 – z · cF)
|
|
|
Using this in the equation for the concentration yields |
| |
| cC | = |
(cF – cC) · cV · z
(1 – z · cF) |
· exp |
HC
kT |
· exp |
DSC
k |
| | | |
| | |
| | |
» |
cF · cV · z
(1 – z · cF) |
· exp |
HC
kT |
· exp |
DSC
k |
|
|
|
|
The last approximation is, of course, attainable if cC
<< cF, and that is the equation given in the backbone
text. |
| |
© H. Föll (Defects - Script)
2.2.1 Extrinsic Point Defects and Agglomerates 
With frame