I'm learning about Brownian motion. I use the approximation of overdamped motion. I read that the average acceleration is $0$ then, but I don't really understand the concept. So, what does overdamped exactly mean, especially in the context of Brownian motion, and why is the acceleration $0$? Thanks!
$\begingroup$
$\endgroup$
1
-
$\begingroup$ Related: physics.stackexchange.com/q/556859/226902 and physics.stackexchange.com/q/666606/226902 $\endgroup$– QuilloCommented Jan 29, 2023 at 14:40
Add a comment
|
1 Answer
$\begingroup$
$\endgroup$
Overdamped means that viscosity forces are much more "relevant" than inertia. When this is the case, essentially any movement will very quickly reach terminal velocity, so the acceleration will be $0$.
As a toy model, imagine trying to push an object through a viscous medium. If we apply some constant force $F$, then Newton's second law gives us the following differential equation: $$m\ddot x=F-b\dot x$$
It is easy to see that terminal velocity is $v_T=F/b$, and the relevant time scale to relax to terminal velocity here is $\tau=m/b$. If the system is overdamped, then $b$ is very large, which makes $\tau$ very small. In other words, the more damping you have, the faster you reach terminal velocity where the acceleration is $0$.
Iin this regime you can create a "trick Newton's second law" where the velocity is proportional to the applied force: $$F=b\dot x$$ Don't show introductory physics students this ;)
answered May 13, 2020 at 19:31