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Non-equilibrium can be obtained in several ways; one always tries to have point
defect concentrations far above equilibrium. | |
What happens during cooling down - rapidly or otherwise?
Question to ponder:
How far can a point defect move during cooling or
what is the total diffusion length Ltotal?
Exercise 4.2-1 |
Ltotal determines - How well quenching works
- Density of agglomerates
- Size of agglomerates
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Quenching, i.e. freezing-in some equilibrium
concentration (or some non-equilibrium concentration) at the low temperature Tquench that was present
at the temperature T. | |
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Irradiation (e.g. with electrons) that mostly produce vacancy - interstitial pairs in a concentration
given by the irradiation intensity and thus will be above thermal equilibrium. |
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After the point defects have been frozen-in, i.e. immobilized, you measure a property
that is sensitive to point defects, most prominently the conductivity at low temperatures, and then study how this property
changes upon annealing, i.e. letting your point defects achieve equilibrium (= disappear). |
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If you started from equilibrium, you will get equilibrium concentration and diffusion data
that must be separated "somehow". | |
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If you started from a non-equilibrium concentrations, you will only
get diffusion data, i.e. migration enthalpies and entropies. |
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© H. Föll (Defects - Script)
