Brownian motion, net displacement, and diffusion - conceptual

Question

I'm having trouble reconciling some conceptual issues of brownian motion.

Let's say we have a box with two compartments separated by a membrane. Solute is at a high concentration on one side, and at a low concentration on the other. We know that the solute will move down its concentration gradient until the concentration is equal.

Here is where I get confused. I have also been told that due to Brownian motion, the net displacement of any given particle is zero. If this is the case, the net displacement of a bunch of particles would be zero. This would not give us the diffusion that is expected as discussed in the preceding paragraph.

So is the net displacement of a given particle actually not zero? Or only zero in certain circumstances? Or have I made some other mistake?

Answer 1

In the situation of two boxes separated by a membrane, there is a very strong difference with the mathematical Brownian motion :

$$\text{The box is finite.}$$

This has a very strong consequcne : the mean displacement cannot be zero anymore.

To understand why, consider for instance a particle starting very close to the border of the box. It can not go beyond the border and therefore, the displacement can only be directed toward the opposite direction. After a long time, the position's probability distribution of any particle becomes uniform in the box, whatever the starting position was.

When there are now a huge number of particles, after an equilibration time, they will fill all the available volume with a uniform density, whatever was their initial distribution.

EDIT: uniform distribution in a finite domain

To see that the proability density of a Brownian motion tends to the uniform distribution, a simple way is to consider a segment $[0,L]$. The differential equation governing the pdf of the particle's position $p(x,t)$ is the heat equation, also called diffusion equation $$\frac{\partial p}{\partial t}(x,t)=D\frac{\partial^2p}{\partial x^2}(x,t).$$ We write $p(x,t)$ as a Fourier series in space $$p(x,t)=\sum_{k\in\mathbb Z}a_k(t)\mathrm e^{\mathrm i2\pi kx/L}.$$ A term $a_k$ corresponds to oscillations of $p$ that have a space periodicity $L/|k|$, so the larger $|k|$ the more $p$ oscillates rapidly with respect to position.

The diffusion equation splits into a series of ordinary differential equation, one for each $k$ $$\frac{\mathrm da_k}{\mathrm dt}(t)=-\frac{4\pi^2Dk^2}{L^2}a_k(t).$$

The solutions are $a_k(t)=a_k(0)\exp\left(-k^2\,4\pi^2Dt/L^2\right)$. We observe that only $a_0(t)$ is not decreasing, such that $p(x,t)\to a_0(0)$ as time $t\to\infty$. This proves that the distribution becomes uniform. We also learn that the larger is $|k|$, the faster the oscillations go to zero.

Spectral analysis of higher level shows that this statement remains true for any domain in any finite dimension, because the Laplacian $(-\Delta)$ has only positive eigenvalues and the uniform function $x\mapsto 1$ is always an eigenfunction, with eigenvalue $0$.