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Besides intrinsic point defects, crystals always contain extrinsic point defects
- impurity atoms on substitutional or interstitial sites. | |
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The concentration cF of extrinsic point defects is pretty
much constant - it cannot be in equilibrium. What is going on in a macroscopic way is given by the phase diagram of crystal
plus impurity atoms | |
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If we discuss extrinsic point defects (in contrast to alloys), we discuss small cF
values. Nevertheless, cF might be much larger than cC, the equilibrium
concentration of vacancies; especially at low temperatures. | |
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The concentration cC of impurity atom - vacancy complexes
is easy to calculate, the decisive parameters are the concentrations of the partners and their binding energy HC |
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| cC | = |
z · cF · cV(T)
1 – z
· cF | · exp |
DSC
k |
· exp |
HC
kT |
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The situation is quite similar to the case of divacancies or multi-vacancies, except that
cF is constant. The concentration of extrinsic-intrinsic complexes in
equilibrium decreases with temperature | |
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With extrinsic point defects the crystal can no longer be in global
equilibrium; what we are looking now is local equilibrium - the minimum of the free enthalpy obtainable under some fixed
circumstances | |
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Fixed circumstances may include that the concentration of the intrinsic point
defects is not in (global) equilibrium. There are many reasons for that: |
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Changing the equilibrium concentration of intrinsic point defects needs two ingredients:
- sources and sinks for intrinsic point defects - external or internal surfaces (= grain boundaries), dislocations - other
defects.
- Sufficient mobility of the point defects to get away from or to the sources and sinks, respectively.
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The latter condition always fails at low temperatures, as a result the formation
of point defect clusters is favored. | |
| cnV |
= (c1V)n · |
z
2 | · exp |
DSnV
k |
· exp |
BnV
kT |
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cnV(T)
increases with exp{BnV / kT}
as soon as cV stays constant. |
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The decisive quantity is the total diffusion length L of a point defect during
the thermal history of its crystal - how far can it "go" before it is frozen into immobility |
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If L > average distance to a sink, we will find mostly equilibrium conditions;
if L < average distance to a sink (Si case!), we will have to expect point defects complexes of
n point defects at a concentration cnV. |
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The upper limit for n is the concentration of point defects contained in the
volume L3. | |
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© H. Föll (Defects - Script)
