T-8: Difference between revisions

Goal: the goal of this set of problems is to derive a criterion for localization on a peculiar lattice, the Bethe lattice.
Techniques: green functions, recursion relations, cavity method.

A criterion for localization

• Green functions and self-energies. Given a lattice with ${\displaystyle N}$ sites ${\displaystyle a}$, we call ${\displaystyle |a\rangle }$ the wave function completely localised in site ${\displaystyle a}$. The Anderson model has Hamiltonian

  ${\displaystyle H=W\sum _{a}\epsilon _{a}|a\rangle \langle a|-\sum _{<a,b>}V_{ab}\left(|a\rangle \langle b|+|b\rangle \langle a|\right)}$

  where the local fields ${\displaystyle \epsilon _{a}}$ are random variables, independent and distributed according to some distribution ${\displaystyle p(\epsilon )}$. We introduce the Green functions ${\displaystyle G_{ab}(z)}$ and the local self-energies ${\displaystyle \sigma _{a}(z):}$ these are functions of a complex variable belonging to the upper half of the complex plane,

  ${\displaystyle z=E+i\eta ,\quad \quad \eta >0}$

  and are defined by

  ${\displaystyle G_{ab}(z)=\langle a|{\frac {1}{z-H}}|b\rangle ,\quad \quad G_{aa}(z)=\langle a|{\frac {1}{z-H}}|a\rangle ={\frac {1}{z-\epsilon _{a}-\sigma _{a}(z)}}.}$

  When the kinetic term ${\displaystyle V}$ in the Hamiltonian vanishes, the local self-energies vanish: they encode how much the energy levels ${\displaystyle \epsilon _{a}}$ (that are the eigenvalues when ${\displaystyle V=0}$) are shifted by the presence of the kinetic term ${\displaystyle V}$. They are random functions, because the Hamiltonian contains randomness. The Green functions and the self-energies encode properties on the spectrum of the Hamiltonian; the local density of eigenvalues ${\displaystyle \rho _{a,N}(E)}$ for an Hamiltonian on a lattice of size ${\displaystyle N}$ is indeed given by

  ${\displaystyle \rho _{a,N}(E)=-{\frac {1}{\pi }}\lim _{\eta \to 0}\Im G_{aa}(E+i\eta )=\sum _{\alpha =1}^{N}|\langle E_{\alpha }|a\rangle |^{2}\delta (E-E_{\alpha }),}$

  where ${\displaystyle E_{\alpha }}$ are the eigenvalues of the full Hamiltonian ${\displaystyle H}$ and ${\displaystyle |E_{\alpha }\rangle }$ the corresponding eigenstates.



• Self-energies and return probabilities. The local self-energies encode some information on the system’s dynamics, and thus on whether localization occurs. Consider a quantum particle initialised on the site ${\displaystyle a}$ at ${\displaystyle t=0}$. The return probability amplitude , i.e. the probability amplitude to find the particle on the same site at later time, is

  ${\displaystyle {\mathcal {A}}_{a}(t)=\theta (t)\langle a|e^{-itH}|a\rangle =\lim _{\eta \to 0}\int {\frac {idE}{2\pi }}e^{-itH}G_{aa}(E+i\eta )=\lim _{\eta \to 0}\int {\frac {idE}{2\pi }}e^{-itH}G_{aa}(E+i\eta )=\lim _{\eta \to 0}\int {\frac {idE}{2\pi }}{\frac {e^{-itH}}{E+i\eta -\epsilon _{a}-\sigma _{a}(E+i\eta )}}.}$

  If the self-energy has a non-zero imaginary part:

  ${\displaystyle \lim _{\eta \to 0}\lim _{N\to \infty }\sigma _{a}(E+i\eta )=R(E)-i\Gamma (E),}$

  then one can easily show (Residue theorem) that the return probability amplitude ${\displaystyle {\mathcal {A}}_{a}(t)}$ decays exponentially

  ${\displaystyle {\mathcal {A}}_{a}(t)\sim A(t)e^{-\gamma t}+B(t),\quad \quad \quad \gamma =\Gamma (\epsilon _{a})+O(V^{4}).}$

  Therefore, the system is not localized, since the probability to find it, at ${\displaystyle t\gg 1}$, in the same configuration where it was at ${\displaystyle t=0}$ decays very fast.

  
  

• A criterion for localization. Motivated by the reasoning above, one can claim that localization occurs whenever the imaginary part of ${\displaystyle \sigma (E+i\eta )}$ goes to zero when ${\displaystyle \eta \to 0}$. Given the randomness, this criterion should however be formulated probabilistically, as

  ${\displaystyle \lim _{\eta \to 0}\lim _{N\to \infty }\mathbb {P} \left(-\Im \sigma _{a}(E+i\eta )>0\right)=0\quad \Longrightarrow \quad {\text{Localization}}}$

Showing that at strong enough disorder this condition is satisfied is the core of Anderson’s 1958 work. Notice that in this criterion, the probability plays the role of an order parameter (like the magnetization in ferromagnets, or the overlap in spin glasses), and the imaginary part ${\displaystyle \eta }$ plays the role of a symmetry breaking field (like the magnetic field in the ferromagnet, or the coupling between replicas in spin glasses). However, the localization transition has nothing to do with equilibrium, i.e., it is not related to a change of structure of the Gibbs Boltzmann measure; rather, it is a dynamical transition (like depinning!). Pushing the analogy with equilibrium phase transitions, one can say that the localised phase corresponds to the disordered phase (the one in which symmetry is not broken, like the paramagnetic phase).


Problems

Problem 8: the Bethe lattice, recursion relations and cavity


A Bethe lattice with ${\displaystyle k=2}$.

The Bethe lattice is a lattice with a regular tree structure: each node has a fixed number of neighbours ${\displaystyle k+1}$, where ${\displaystyle k}$ is the branching number, and there are no loops (see sketch). In these problems we consider the Anderson model on such lattice.




1. Green functions identities. Consider an Hamiltonian split into two parts, ${\displaystyle H=H_{0}+V}$. Show that the following general relation for the Green functions holds:

   ${\displaystyle G=G^{0}+G^{0}VG,\quad \quad G^{0}={\frac {1}{z-H_{0}}},\quad \quad G={\frac {1}{z-H}}.}$



2. Cavity equations. We now apply this to a specific example: we consider a Bethe lattice, and choose one site 0 as the root. We then choose ${\displaystyle V}$ to be the kinetic terms connecting the root to its ${\displaystyle k+1}$ neighbours ${\displaystyle a_{i}}$,

   ${\displaystyle V=-\sum _{i=1}^{k+1}V_{0a_{i}}\left(|a_{i}\rangle \langle 0|+|0\rangle \langle a_{i}|\right)}$

   For all the ${\displaystyle a_{i}}$ with ${\displaystyle i=1,\cdots ,k+1}$ we introduce the notation

   ${\displaystyle G_{a_{i}}^{\text{cav}}\equiv G_{a_{i}a_{i}}^{0},\quad \quad \sigma _{a_{i}}^{\text{cav}}\equiv \sigma _{a_{i}a_{i}}^{0},}$

   where Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle \sigma^0 } is the self energy associated to Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle G^0 } . Show that, due to the geometry of the lattice, with this choice of Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle V } the Hamiltonian Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle H_0 } is decoupled and ${\displaystyle G_{a_{i}}^{\text{cav}}}$ is the local Green function that one would have obtained removing the root 0 from the lattice, i.e., creating a “cavity” (hence the suffix). Moreover, using the relation above show that

   ${\displaystyle G_{00}(z)={\frac {1}{z-\epsilon _{0}-\sum _{i=1}^{k+1}V_{0a_{i}}^{2}G_{a_{i}}^{\text{cav}}(z)}}}$

   Iterating this argument, show that if ${\displaystyle \partial a_{i}}$ denotes the collection of “descendants" of ${\displaystyle a_{i}}$, i.e. sites that are nearest neighbours of ${\displaystyle a_{i}}$ except the root, then

   ${\displaystyle G_{a_{i}}^{\text{cav}}(z)={\frac {1}{z-\epsilon _{a_{i}}-\sum _{b\in \partial a_{i}}V_{a_{i}b}^{2}G_{b}^{\text{cav}}(z)}},\quad \quad \sigma _{a_{i}}^{\text{cav}}(z)=\sum _{b\in \partial a_{i}}V_{a_{i}b}^{2}G_{b}^{\text{cav}}(z)=\sum _{b\in \partial a_{i}}{\frac {V_{a_{i}b}^{2}}{z-\epsilon _{b}-\sigma _{b}^{\text{cav}}(z)}}}$



3. Equations for the distribution. Justify why the cavity functions appearing in the denominators in the last equations above are independent and identically distributed random variables, and therefore the cavity equations can be interpreted as self-consistent equations for the distribution of the cavity functions.


4. The “localized" solution. We set ${\displaystyle z=E+i\eta }$ and ${\displaystyle \sigma _{a}^{\text{cav}}(z)=R_{a}(z)-i\Gamma _{a}(z)}$. Show that the cavity equation for the self-energies is equivalent to the following pair of coupled equations:

   ${\displaystyle \Gamma _{a}=\sum _{b\in \partial a}t_{ab}^{2}{\frac {\Gamma _{b}+\eta }{(E-\epsilon _{b}-R_{b})^{2}+(\Gamma _{b}+\eta )^{2}}},\quad \quad R_{a}=\sum _{b\in \partial a}t_{ab}^{2}{\frac {E-\epsilon _{b}-R_{b}}{(E-\epsilon _{b}-R_{b})^{2}+(\Gamma _{b}+\eta )^{2}}}}$

   Justify why the solution corresponding to localization, ${\displaystyle \Gamma _{a}=0}$, is always a solution when ${\displaystyle \eta \to 0}$; moreover, in the localized phase when ${\displaystyle \eta }$ is finite but small one has ${\displaystyle \Gamma _{a}\sim O(\eta )}$. How can one argue that this solution has to be discarded, i.e. that delocalisation occurs?







Check out: key concepts of this TD

Green functions, self-energies, return probability amplitude, decay rates, trees and cavity method, the criterion for localization.

References

• The Anderson model was formulated by P. W. Anderson in 1958, in the paper Absence of diffusion in certain random lattices , Phys. Rev. 109, 1492.