T-7: Difference between revisions

Goal: the goal of this set of problems is to derive an estimate for the transition point for the Anderson model on the Bethe lattice.
Techniques: cavity method, stability analysis.

A criterion for localization

• Green functions and self-energies. Given a lattice ${\displaystyle \Lambda }$ with sites ${\displaystyle a}$, we call ${\displaystyle |a\rangle }$ the wave function completely localised in site ${\displaystyle a}$. The Anderson model has Hamiltonian ${\displaystyle H=W\sum _{a}\epsilon _{a}|a\rangle \langle a|+\sum _{<a,b>}V_{ab}\left(|a\rangle \langle b|+|b\rangle \langle a|\right)=H_{0}+V}$

  where the local fields ${\displaystyle \epsilon _{a}}$ are random variables. We introduce the Green functions ${\displaystyle G_{ab}(z)}$: these are functions of a complex variable belonging to the upper half of the complex plane, and are defined by [NOTA SU STILTJIES]

  ${\displaystyle G_{ab}(z)=\langle a|{\frac {1}{z-H}}|b\rangle }$

  The local self-energies ${\displaystyle \sigma _{a}(z)}$ are functions defined by the equality

  ${\displaystyle G_{aa}(z)=\langle a|{\frac {1}{z-H}}|a\rangle ={\frac {1}{z-\epsilon _{a}-\sigma _{a}(z)}}.}$ It is clear that when the kinetic term ${\displaystyle V}$ in the Hamiltonian vanishes, the local self-energies vanish; these quantities encode how much the energy levels ${\displaystyle \epsilon _{a}}$ are shifted by the presence of the kinetic term ${\displaystyle V}$. They are random functions, with a distribution that

Y . - model on the be the lattice - self energy -criterion for localization - links to ergo breaking

Problem 7.1:

the cavity equation and the linearisation




Problem 7.2:

Check out: key concepts of this TD

References

• Bouchaud. Weak ergodicity breaking and aging in disordered systems [1]