Interfaces: thermal shaking

Consider domain wall ${\displaystyle h(r,t)}$ fluctuating at equilibrium at the temperature ${\displaystyle T}$. Here ${\displaystyle t}$ is time, ${\displaystyle r}$ defines the d-dimensional coordinate of the interface and ${\displaystyle h}$ is the scalar height field. Hence, the domain wall separating two phases in a film has ${\displaystyle d=1,r\in {\cal {R}}}$, in a solid instead ${\displaystyle d=2,r\in {\cal {{R}^{2}}}}$.

Two assumptions are done:

• Overhangs, pinch-off are neglected, so that ${\displaystyle h(r,t)}$ is a scalar univalued function.
• The dynamics is overdamped, so that we can neglect the inertial term.

Derivation

The Langevin equation of motion is

${\displaystyle \partial _{t}h(r,t)=-\mu {\frac {\delta E_{pot}}{\delta h(r,t)}}+\eta (r,t)}$

The first term ${\displaystyle -\delta E_{pot}/\delta h(r,t)}$ is the elastic force trying to smooth the interface, the mobility ${\displaystyle \mu }$ is the inverse of the viscosity. The second term is the Langevin noise. It is Guassian and defined by

${\displaystyle \langle \eta (r,t)\rangle =0,\;\langle \eta (r',t')\eta (r,t)\rangle =2dD\delta ^{d}(r-r')\delta (t-t')}$

The symbol ${\displaystyle \langle \ldots \rangle }$ indicates the average over the thermal noise and the diffusion constant is fixed by the Einstein relation ${\displaystyle D=\mu K_{B}T}$. We set ${\displaystyle \mu =K_{B}=1}$

The potential energy of surface tension (${\displaystyle \nu }$ is the stiffness) can be expanded at the lowest order in the gradient:

${\displaystyle E_{pot}=\nu \int d^{d}r{\sqrt {1+(\nabla h)^{2}}}\sim {\text{const.}}+{\frac {\nu }{2}}\int d^{d}r(\nabla h)^{2}}$

Hence, we have the Edwards Wilkinson equation:

${\displaystyle \partial _{t}h(r,t)=\nu \nabla ^{2}h(r,t)+\eta (r,t)}$