Revision as of 16:59, 27 December 2023

Goal: The physical properties of many materials are controlled by the interfaces embedded in it. This is the case of the dislocations in a crystal, the domain walls in a ferromagnet or the vortices in a supercoductors. In the next lecture we will discuss how impurities affect the behviour of these interfaces. Today we focus on thermal fluctuations and introduce two important equations for the interface dynamics: the Edward Wilkinson euqation and the Kardar Parisi Zhang equation.

An interface at Equilibrium: the Edward Wilkinson equation

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

Two assumptions are done:

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

Derivation

The Langevin equation of motion is

\partial_{t} h (r, t) = - μ \frac{δ E_{p o t}}{δ h (r, t)} + η (r, t)

The first term $- δ E_{p o t} / δ h (r, t)$ is the elastic force trying to smooth the interface, the mobility $μ$ is inversily proportional to the viscosity. The second term is the Langevin Gaussian noise defined by the correlations

⟨ η (r, t) ⟩ = 0, ⟨ η (r^{'}, t^{'}) η (r, t) ⟩ = 2 D δ^{d} (r - r^{'}) δ (t - t^{'})

The symbol $⟨ \dots ⟩$ indicates the average over the thermal noise. The diffusion constant is fixed by the Eistein relation (fluctuation-dissipation theorem):

D = μ K_{B} T

The potential energy of surface tension can be expanded at the lowest order in the gradient:

E_{p o t} = σ \int d^{d} r \sqrt{1 + (\nabla h)^{2}} \sim const. + \frac{σ}{2} \int d^{d} r (\nabla h)^{2}

Setting $μ = 1, σ = 1 / 2$ we have the Edward Wilkinson equation:

\partial_{t} h (r, t) = \nabla^{2} h (r, t) + η (r, t)

Scaling Invariance

The equation enjoys of a continuous symmetry because $h (r, t)$ and $h (r, t) + c$ cannot be distinguished. This is a conndition os scale invariance:

h (b r, b^{z} t) \overset{i n l a w}{\sim} b^{α} h (r, t)

Here $z, α$ are the dynamic and the roughness exponent rispectively. From dimensional analysis

b^{α - z} \partial_{t} h (r, t) = b^{α - 2} \nabla^{2} h (r, t) + b^{- d / 2 - z / 2} η (r, t)

From which you get $z = 2$ in any dimension and a rough interface below $d = 2$ with $α = (2 - d) / 2$

Exercise L2-A: Solve Edward-Wilkinson

For simplicity, consider a line of size L with periodic boundary conditions. It is useful to introduce the Fourier modes:

@@ Line 45: / Line 45: @@
 </math></center>
 From which you get <math> z=2 </math> in any dimension and a rough interface below <math> d=2 </math> with <math> \alpha =(2-d)/2 </math>
-== Exercise L2-A: Solve Edward-Wilkinson ==
+=== Exercise L2-A: Solve Edward-Wilkinson ===
+For simplicity, consider a line of size L with periodic boundary conditions. It is useful to introduce the Fourier modes:

L-2: Difference between revisions

Revision as of 16:59, 27 December 2023

Contents

An interface at Equilibrium: the Edward Wilkinson equation

Derivation

Scaling Invariance

Exercise L2-A: Solve Edward-Wilkinson

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L-2: Difference between revisions

Revision as of 16:59, 27 December 2023

An interface at Equilibrium: the Edward Wilkinson equation

Derivation

Scaling Invariance

Exercise L2-A: Solve Edward-Wilkinson

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