Introduction: Interfaces and Directed Polymers

The physical properties of many materials are governed by manifolds embedded in them. Examples include: dislocations in crystals, domain walls in ferromagnets or vortex lines in superconductors. We fix the following notation: - ${\displaystyle D}$: spatial dimension of the embedding medium – ${\displaystyle d}$: internal dimension of the manifold – ${\displaystyle N}$: dimension of the displacement (or height) field

These satisfy the relation:

${\displaystyle D=d+N}$

We focus on two important cases:

Directed Polymers (d = 1)

The configuration is described by a vector function: ${\displaystyle \overrightarrow{x}(t)}$, where ${\displaystyle t}$ is the internal coordinate. The polymer lives in ${\displaystyle D=1+N}$ dimensions.

Examples: vortex lines, DNA strands, fronts.

Although polymers may form loops, we restrict to directed polymers, i.e., configurations without overhangs or backward turns.

Interfaces (N = 1)

The interface is described by a scalar height field: ${\displaystyle h(\overrightarrow{r},t)}$, where ${\displaystyle \overrightarrow{r}\in {\mathbb{ℝ}}^d}$ is the internal coordinate and ${\displaystyle t}$ represents time.

Examples: domain walls and propagating fronts

Again we neglect overhangs or pinch-off: ${\displaystyle h(\overrightarrow{r},t)}$ is single-valued

Note that using our notation the 1D front is both an interface and a directed polymer

Thermal Interfaces

The dynamics is overdamped, so that we can neglect the inertial term. 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

${\displaystyle ⟨\eta (r,t)⟩=0,⟨\eta (r^{\prime },t^{\prime })\eta (r,t)⟩=2dD{\delta }^d(r-r^{\prime })\delta (t-t^{\prime })}$

The symbol ${\displaystyle ⟨\dots ⟩}$ 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:

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

Hence, we have the Edwards Wilkinson equation:

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

Scaling Invariance

The equation enjoys of a continuous symmetry because ${\displaystyle h(r,t)}$ and ${\displaystyle h(r,t)+c}$ cannot be distinguished. This is a condition of scale invariance:

${\displaystyle h(br,b^{z}t)\stackrel{inlaw}{\sim }{b}^{\alpha }h(r,t)}$

Here ${\displaystyle z,\alpha }$ are the dynamic and the roughness exponent respectively. From dimensional analysis

${\displaystyle b^{\alpha -z}{\partial }_{t}h(r,t)=b^{\alpha -2}{\mathrm{\nabla }}^{2}h(r,t)+b^{-d/2-z/2}\eta (r,t)}$

From which you get ${\displaystyle z=2}$ in any dimension and a rough interface below ${\displaystyle d=2}$ with ${\displaystyle \alpha =(2-d)/2}$.

Width of the interface

Consider a 1-dimensional line of size L with periodic boundary conditions. We consider the width square of the interface

${\displaystyle w_2(t)={\left[{\displaystyle \underset{0}{\overset{L}{\int }}}\frac{dr}{L}(h(r,t)-{\displaystyle \underset{0}{\overset{L}{\int }}}\frac{dr}{L}h(r,t))\right]}^2}$

It is useful to introduce the Fourier modes:

${\displaystyle {\hat{h}}_q(t)=\frac{1}{L}{\displaystyle \underset{0}{\overset{L}{\int }}}{e}^{iqr}h(r,t),h(r,t)=\sum _q{e}^{-iqr}{\hat{h}}_q(t)}$

Here ${\displaystyle q=2\pi n/L,n=\dots ,-1,0,1,\dots }$ and recall ${\displaystyle {\displaystyle \underset{0}{\overset{L}{\int }}}dr{e}^{iqr}=L{\delta }_{q,0}}$. using de Parseval theorem for the Fourier series

${\displaystyle w_2(t)=\sum _{q\ne 0}|{\hat{h}}_q(t){|}^2=\sum _{q\ne 0}{({\hat{h}}_q(t){\hat{h}}_{-q}(t))}^2}$

In the last step we used that ${\displaystyle {\hat{h}}_q^{*}(t)={\hat{h}}_{-q}(t)}$.

Solution in the Fourier space

show that the EW equation writes

${\displaystyle {\partial }_t{\hat{h}}_q(t)=-\nu q^2{\hat{h}}_q(t)+{\eta }_q(t),\text{with}⟨{\eta }_{q_1}(t^{\prime }){\eta }_{q_2}(t)⟩=\frac{2T}{L}{\delta }_{q_1,-q_2}\delta (t-t^{\prime })}$

The solution of this first order linear equation writes

${\displaystyle {\hat{h}}_q(t)={\hat{h}}_q(0)e^{-\nu q^{2}t}+{\displaystyle \underset{0}{\overset{t}{\int }}}ds{e}^{-\nu q^2(t-s)}{\eta }_q(s)}$

• Assume that the interface is initially flat, namely ${\displaystyle {\hat{h}}_q(0)=0}$. Show that

${\displaystyle ⟨{\hat{h}}_q(t){\hat{h}}_{-q}(t)⟩=\{\begin{array}{ll}{\displaystyle \frac{T(1-e^{-2\nu q^{2}t})}{L\nu q^2}},& q\ne 0,\\ \frac{2T}{L}t,& q=0.\end{array}}$

• The mean width square grows at short times and saturates at long times:

${\displaystyle ⟨w_2(t)⟩={\displaystyle \frac{T}{L\nu }}\sum _{q\ne 0}{\displaystyle \frac{1-e^{-2\nu q^{2}t}}{q^2}}=\{\begin{array}{ll}T\sqrt{\frac{2t}{\pi \nu }},& t\ll L^2,\\ \frac{T}{\nu }\frac{L}{12},& t\gg L^2.\end{array}}$

Directed polymers in random media

Let us consider polymers ${\displaystyle x(\tau )}$ of length ${\displaystyle t}$, starting in ${\displaystyle 0}$ and ending in ${\displaystyle x}$ and at thermal equlibrium at temperature ${\displaystyle T}$. The partition function of the model writes as

${\displaystyle Z(x,t)={\displaystyle \underset{x(0)=0}{\overset{x(t)=x}{\int }}}{𝒟}x(\tau )\exp [-\frac{1}{T}{\displaystyle \underset{0}{\overset{t}{\int }}}d\tau \frac{1}{2}({\partial }_{\tau }x{)}^2+V(x(\tau ),\tau )]}$

For simplicity, we assume a white noise, ${\displaystyle \overline{V(x,\tau )V(x^{\prime },{\tau }^{\prime })}=D\delta (x-x^{\prime })\delta (\tau -{\tau }^{\prime })}$. Here, the partition function is written as a sum over all possible paths, corresponding to all possible polymer configurations that start at ${\displaystyle 0}$ and end at ${\displaystyle x}$, weighted by the appropriate Boltzmann factor.

Polymer partition function and propagator of a quantum particle

Let's perform the following change of variables: ${\displaystyle \tau =i{t}^{\prime }}$. We also identifies ${\displaystyle T}$ with ${\displaystyle \hslash }$ and ${\displaystyle \tilde{t}=-it}$ as the time.

${\displaystyle Z(x,\tilde{t})={\displaystyle \underset{x(0)=0}{\overset{x(\tilde{t})=x}{\int }}}{𝒟}x(t^{\prime })\exp [\frac{i}{\hslash }{\displaystyle \underset{0}{\overset{\tilde{t}}{\int }}}d{t}^{\prime }\frac{1}{2}({\partial }_{t^{\prime }}x{)}^2-V(x(t^{\prime }),t^{\prime })]}$

Note that ${\displaystyle S[x]={\displaystyle \underset{0}{\overset{\tilde{t}}{\int }}}d{t}^{\prime }\frac{1}{2}({\partial }_{t^{\prime }}x{)}^2-V(x(t^{\prime }),t^{\prime })}$ is the classical action of a particle with kinetic energy ${\displaystyle \frac{1}{2}({\partial }_{\tau }x{)}^2}$ and time dependent potential ${\displaystyle V(x(\tau ),\tau )}$, evolving from time zero to time ${\displaystyle \tilde{t}}$. From the Feymann path integral formulation, ${\displaystyle Z[x,\tilde{t}]}$ is the propagator of the quantum particle.

In absence of disorder, one can find the propagator of the free particle, that, in the original variables, writes:

${\displaystyle Z_{\text{free}}(x,t)=\frac{e^{-x^2/(2Tt)}}{\sqrt{2\pi Tt}}}$