Eigenstates

Without disorder, the eigenstates are delocalized plane waves.

In the presence of disorder, three scenarios can arise: Delocalized eigenstates, where the wavefunction remains extended; Localized eigenstates, where the wavefunction is exponentially confined to a finite region; Multifractal eigenstates, occurring at the mobility edge, where the wavefunction exhibits a complex, scale-dependent structure.

To distinguish these regimes, it is useful to introduce the inverse participation ratio (IPR).

${\displaystyle IPR(q)=\sum _n|{\psi }_n{|}^{2q}\sim L^{-{\tau }_q}}$

Delocalized eigenstates

In this case, ${\displaystyle |{\psi }_n{|}^2\approx L^{-d}}$. Hence, we expect

${\displaystyle IPR(q)=L^{d(1-q)}{\tau }_q=d(1-q)}$

Localized eigenstates

In this case, ${\displaystyle |{\psi }_n{|}^2\approx 1/{\xi }_{\text{loc}}^{1/d}}$ for ${\displaystyle {\xi }_{\text{loc}}^d}$ sites and almost zero elsewhere. Hence, we expect

${\displaystyle IPR(q)=\text{const},{\tau }_q=0}$

Multifractal eigenstates

The exponent ${\displaystyle {\tau }_q}$ is called multifractal exponent . It is a non decreasing function with q with some special points:

• ${\displaystyle {\tau }_0=-d}$ because the wave fuction is defined on all sites, in general ${\displaystyle {\tau }_0}$ is the fractal dimension of the object we are considering. It is simply a geometrical property.
• ${\displaystyle {\tau }_1=0}$ imposed by normalization.

To have multifractal behaviour we expect

${\displaystyle |{\psi }_n{|}^2\approx L^{-\alpha }\text{for}{L}^{f(\alpha )}\text{sites}}$

The exponent ${\displaystyle \alpha }$ is positive and ${\displaystyle f(\alpha )}$ is called multifractal spectrum . Its maximum is the fractal dimension of the object, in our case d. We can determine the relation between multifractal spectrum ${\displaystyle f(\alpha )}$ and exponent ${\displaystyle {\tau }_q}$

${\displaystyle IPR(q)=\sum _n|{\psi }_n{|}^{2q}\sim \int d\alpha L^{-\alpha q}{L}^{f(\alpha )}}$

for large L

${\displaystyle \tau (q)=\underset{\alpha }{\min }(\alpha q-f(\alpha ))}$

This means that for ${\displaystyle {\alpha }^{*}(q)}$ that verifies ${\displaystyle f^{\prime }({\alpha }^{*}(q))=q}$ we have

${\displaystyle \tau (q)={\alpha }^{*}(q)q-f({\alpha }^{*}(q))}$

Delocalized wave functions have a simple spectrum: For ${\displaystyle \alpha =d}$, we have ${\displaystyle f(\alpha =d)=d}$ and ${\displaystyle f(\alpha \ne d)=-\mathrm{\infty }}$. Then ${\displaystyle {\alpha }^{*}(q)=d}$ becomes ${\displaystyle q}$ independent. Multifractal wave functions smooth this edge dependence and display a smooth spectrum with a maximum at ${\displaystyle {\alpha }_0}$ with ${\displaystyle f({\alpha }_0)=d}$. At ${\displaystyle q=1}$, ${\displaystyle f^{\prime }({\alpha }_1)=1}$ and ${\displaystyle f({\alpha }_1)={\alpha }_1}$.

Sometimes one writes:

${\displaystyle IPR(q)=L^{D_q(1-q)}{\tau }_q=D_q(1-q)}$

Here ${\displaystyle D_q}$ is q-dependent multifractal dimension, smaller than ${\displaystyle d}$ and larger than zero.

Larkin model

In your homewoork you solved a toy model for the interface:

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

For simplicity, we assume Gaussian disorder ${\displaystyle \overline{F(r)}=0}$, ${\displaystyle \overline{F(r)F(r^{\prime })}={\sigma }^2{\delta }^d(r-r^{\prime })}$.

You proved that:

• the roughness exponent of this model is ${\displaystyle {\zeta }_L=\frac{4-d}{2}}$ below dimension 4
• The force per unit length acting on the center of the interface is ${\displaystyle f=\sigma /\sqrt{L^d}}$
• at long times the interface shape is

${\displaystyle \overline{h(q)h(-q)}=\frac{{\sigma }^2}{q^{d+2{\zeta }_L}}}$

In the real depinning model the disorder is however a non-linear function of h. The idea of Larkin is that this linearization is correct up, ${\displaystyle r_f}$ the length of correlation of the disorder along the h direction . This defines a Larkin length. Indeed from

${\displaystyle \overline{(h(r)-h(0){)}^2}={\displaystyle \underset{d}{\overset{d}{\int }}}q(\overline{h(q)h(-q)}(1-\cos (qr)\sim {\sigma }^2{r}^{2{\zeta }_L}}$

You get

${\displaystyle \overline{(h({\ell }_L)-h(0){)}^2}=r_f^2{\ell }_L={\left(\frac{r_f}{\sigma }\right)}^{1/{\zeta }_L}}$

Above this scale, roguhness change and pinning starts with a crtical force

${\displaystyle f_c=\frac{\sigma }{{\ell }_L^{d/(2{\zeta }_L)}}}$

In ${\displaystyle d=1}$ we have ${\displaystyle {\ell }_L={\left(\frac{r_f}{\sigma }\right)}^{2/3}}$