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---
title: "Fick's laws"
sort_title: "Fick's laws"
date: 2021-09-05
categories:
- Physics
- Mathematics
layout: "concept"
---
**Fick's laws of diffusion** govern the majority of diffusion processes,
where a certain "impurity" substance redistributes itself through a medium over time.
A diffusion process that obeys Fick's laws is called **Fickian**,
as opposed to **non-Fickian** or **anomalous diffusion**.
## Fick's first law
**Fick's first law** states that diffusing matter
moves from regions of high concentration to regions of lower concentration,
at a rate proportional to the difference in concentration.
Let $$\vec{J}$$ be the **diffusion flux** (with unit $$\mathrm{m}^{-2} \mathrm{s}^{-1}$$),
whose magnitude and direction describes the "flow" of diffusing matter.
Formally, Fick's first law predicts that the flux
is proportional to the gradient of the concentration $$C$$ (with unit $$\mathrm{m}^{-3}$$):
$$\begin{aligned}
\boxed{
\vec{J}
= - D \: \nabla C
}
\end{aligned}$$
Where $$D$$ (with unit $$\mathrm{m}^{2}/\mathrm{s}$$)
is known as the **diffusion coefficient** or **diffusivity**,
and depends on both the medium and the diffusing substance.
Fick's first law is a general physical principle,
which was discovered experimentally,
and thus does not have a general derivation.
Proofs for specific systems do exist,
but they say more about those systems
than about diffusion in general.
## Fick's second law
To derive **Fick's second law**, we demand that matter is conserved,
i.e. the diffusing species is not created or destroyed anywhere.
Suppose that an arbitrary volume $$V$$ contains an amount $$M$$ of diffusing matter,
distributed in space according to $$C(\vec{r})$$, such that:
$$\begin{aligned}
M
\equiv \int_V C \dd{V}
\end{aligned}$$
Over time $$t$$, matter enters/leaves $$V$$.
Let $$S$$ be the surface of $$V$$, and $$\vec{J}$$ the diffusion flux,
then $$M$$ changes as follows, to which we apply the divergence theorem:
$$\begin{aligned}
\dv{M}{t}
= - \int_S \vec{J} \cdot \dd{\vec{S}}
= - \int_V \nabla \cdot \vec{J} \dd{V}
\end{aligned}$$
For comparison, we can also just differentiate the definition of $$M$$ directly:
$$\begin{aligned}
\dv{M}{t}
= \dv{}{t}\int_V C \dd{V}
= \int_V \pdv{C}{t} \dd{V}
\end{aligned}$$
Above, we have two valid expressions for $$\idv{M}{t}$$,
which must be equal, so stripping the integrals leads to this **continuity equation**:
$$\begin{aligned}
\pdv{C}{t}
= - \nabla \cdot \vec{J}
\end{aligned}$$
From Fick's first law, we already have an expression for $$\vec{J}$$.
Substituting this into the continuity equation yields
the general form of Fick's second law:
$$\begin{aligned}
\boxed{
\pdv{C}{t}
= \nabla \cdot \Big( D \: \nabla C \Big)
}
\end{aligned}$$
Usually, it is assumed that $$D$$ is constant
with respect to space $$\vec{r}$$ and concentration $$C$$,
in which case Fick's second law reduces to:
$$\begin{aligned}
\pdv{C}{t} = D \: \nabla^2 C
\end{aligned}$$
## Fundamental solution
Fick's second law has exact solutions for many situations,
but the most important one is arguably the **fundamental solution**.
Consider a 1D system (for simplicity) with constant diffusivity $$D$$,
where the initial concentration $$C(x, 0)$$ is
a [Dirac delta function](/know/concept/dirac-delta-function/):
$$\begin{aligned}
C(x, 0)
= \delta(x - x_0)
\end{aligned}$$
By solving Fick's second law with this initial condition,
$$C$$'s time evolution turns out to be:
$$\begin{aligned}
H(x - x_0, t)
\equiv C(x, t)
= \frac{1}{\sqrt{4 \pi D t}} \exp\!\Big( \!-\!\frac{(x - x_0)^2}{4 D t} \Big)
\end{aligned}$$
This result is a normalized Gaussian,
as a consequence of
the [central limit theorem](/know/concept/central-limit-theorem/):
the diffusion behaviour is a sum of many independent steps
(i.e. molecular collisions).
The standard deviation is $$\sqrt{2 D t}$$,
meaning that the distance of a diffusion is proportional to $$\sqrt{t}$$.
This solution $$H$$ is extremely useful,
because any initial concentration $$C(x, 0)$$ can be written as
a convolution of itself with a delta function:
$$\begin{aligned}
C(x, 0)
= (C * \delta)(x)
= \int_{-\infty}^\infty C(x_0, 0) \: \delta(x - x_0) \dd{x_0}
\end{aligned}$$
In other words, any function is a linear combination of delta functions.
Fick's second law is linear,
so the overall solution $$C(x, t)$$ is the same combination of fundamental solutions $$H$$:
$$\begin{aligned}
C(x, t)
= (C * H)(x)
&= \int_{-\infty}^\infty C(x_0, 0) \: H(x - x_0, t) \dd{x_0}
\\
&= \int_{-\infty}^\infty \frac{1}{\sqrt{4 \pi D t}} \exp\!\Big( \!-\!\frac{(x - x_0)^2}{4 D t} \Big) \: C(x_0, 0) \dd{x_0}
\end{aligned}$$
This technique is analogous to using
the [impulse response](/know/concept/impulse-response/)
of a linear operator to extrapolate all its inhomogeneous solutions.
The difference is that here, we used the initial condition
instead of the forcing function.
## References
1. U.F. Thygesen,
*Lecture notes on diffusions and stochastic differential equations*,
2021, Polyteknisk Kompendie.
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