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There is no technology without diffusion and no "high"
technology without controlled diffusion. |
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 | – Diffusion = |
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Fick's first law is the foundation of phenomenological diffusion. |
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| 1. |
ji | = – |
D · Ñci |
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| 2. |
¶c
¶t | = |
div (D · Ñc) = D
· Dc |
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Fick's second law is simply the continuity equation for diffusing entities (without
changing the total particle number). | |
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Diffusion is synonymous with "random walk". The basic equation for random walk relates
the diffusion length L to the number of jumps N and the (average) distance a covered
in one jump. | |
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The relation between the atomic point of view and the phenomenological point of
view goes back to Einstein; n is the jump frequency N/t. |
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| D | = |
g · a2 · n |
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= | D0 · exp – |
HM
kT |
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The important parameter for atomic diffusion is now the migrations enthalpy HM
of the atom (or better defect) under consideration, and, somewhat less important, the pre-exponential factor D0
that contains the migration entropy SM and the lattice parameters. |
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If we combine the equations for D with the one for random walk,
we obtain the Einstein-Smolukowski relation | |
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Read backwards it tells us that the diffusion lengtt L is given by the square
root of diffusion coefficient D times diffusion time t. |
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© H. Föll (Defects - Script)
