In condensed matter physics, lattice diffusion (also called bulk or volume diffusion) refers to atomic diffusion within a crystalline lattice,[1] which occurs by either interstitial or substitutional mechanisms. In interstitial lattice diffusion, a diffusant (such as carbon in an iron alloy), will diffuse in between the lattice structure of another crystalline element. In substitutional lattice diffusion (self-diffusion for example), the atom can only move by switching places with another atom. Substitutional lattice diffusion is often contingent upon the availability of point vacancies throughout the crystal lattice. Diffusing particles migrate from point vacancy to point vacancy by the rapid, essentially random jumping about (jump diffusion). Since the prevalence of point vacancies increases in accordance with the Arrhenius equation, the rate of crystal solid state diffusion increases with temperature. For a single atom in a defect-free crystal, the movement can be described by the "random walk" model.
An atom diffuses in the interstitial mechanism by passing from one interstitial site to one of its nearest neighboring interstitial sites. The movement of atoms can be described as jumps, and the interstitial diffusion coefficient depends on the jump frequency. The jump frequency,
\Gamma
\Gamma=zv\exp\left(
| -\DeltaGm | |
| RT |
\right)
where
z
v
\DeltaGm
\DeltaGm
\DeltaHm
-T\DeltaSm
D=\left[
| 1 | |
| z |
\alpha2zv\exp
| \DeltaSm | |
| R |
\right]\exp
| -\DeltaHm | |
| RT |
where
\alpha
The diffusion coefficient can be simplified to an Arrhenius equation form:
D=D0\exp
| -QI | |
| RT |
where
D0
D0=\tfrac{1}{z}\alpha2zv\exp\tfrac{\DeltaSm}{R}
QI
QI=\DeltaHm
In the case of interstitial diffusion, the activation enthalpy
QI
QI
The rate of self-diffusion can be measured experimentally by introducing radioactive A atoms (A*) into pure A and measuring the rate at which penetration occurs at various temperatures. A* and A atoms have approximately identical jump frequencies since they are chemically identical. The diffusion coefficient of A* and A can be related to the jump frequency and expressed as:
| * | |
| D | |
| A |
=DA=
| 1 | |
| 6 |
\alpha2\Gamma
where
| * | |
| D | |
| A |
DA
\Gamma
\alpha
An atom can make a successful jump when there are vacancies nearby and when it has enough thermal energy to overcome the energy barrier to migration. The number of successful jumps an atom will make in one second, or the jump frequency, can be expressed as:
\Gamma=zvXv\exp
| -\DeltaGm | |
| RT |
where
z
v
Xv
\DeltaGm
Xv=
| e | |
| X | |
| v |
=\exp
| -\DeltaGv | |
| RT |
where
\DeltaGv
The diffusion coefficient in thermodynamic equilibrium can be expressed with
\DeltaGm
\DeltaGv
DA=
| 1 | |
| 6 |
\alpha2zv\exp
| -(\DeltaGm+\DeltaGv) | |
| RT |
Substituting ΔG = ΔH – TΔS gives:
DA=
| 1 | |
| 6 |
\alpha2zv\exp
| \DeltaSm+\DeltaSv | \exp | |
| R |
| -(\DeltaHm+\DeltaHv) | |
| RT |
The diffusion coefficient can be simplified to an Arrhenius equation form:
DA=D0\exp
| -QS | |
| RT |
where
D0
D0=
| 1 | |
| 6 |
\alpha2zv\exp
| \DeltaSm+\DeltaSv | |
| R |
QS
QS=\DeltaHm+\DeltaHv
Compared to that of interstitial diffusion, the activation energy for self-diffusion has an extra term (ΔHv). Since self-diffusion requires the presence of vacancies whose concentration depends on ΔHv.
Diffusion of a vacancy can be viewed as the jumping of a vacancy onto an atom site. It is the same process as the jumping of an atom into a vacant site but without the need to consider the probability of vacancy presence, since a vacancy is usually always surrounded by atom sites to which it can jump. A vacancy can have its own diffusion coefficient that is expressed as:
Dv=
| 1 | |
| 6 |
\alpha2\Gammav
where
\Gammav
The diffusion coefficient can also be expressed in terms of enthalpy of migration (
\DeltaHm
\DeltaSm
Dv=
| 1 | |
| 6 |
\alpha2zv\exp
| \DeltaSm | \exp | |
| R |
| -\DeltaHm | |
| RT |
Comparing the diffusion coefficient between self-diffusion and vacancy diffusion gives:
Dv=
| DA | ||||||
|
where the equilibrium vacancy fraction
| e | |
| X | |
| v |
=\exp
| -\DeltaGv | |
| RT |
In a system with multiple components (e.g. a binary alloy), the solvent (A) and the solute atoms (B) will not move in an equal rate. Each atomic species can be given its own intrinsic diffusion coefficient
\tilde{D}A
\tilde{D}B
\tilde{D}
\tilde{D}=\tilde{D}AXB+\tilde{D}BXA
where
XA
XB