Revision as of 18:27, 16 March 2024

Goal: we will introduce the Anderson model, discuss the behaviour as a function of the dimension. In 1d localization can be connected to the product of random matrices.

Anderson model (tight bindind model)

We consider disordered non-interacting particles hopping between nearest neighbors sites on a lattice. The hamiltonian reads:

H = - t \sum_{< i, j >} (c_{i}^{†} c_{j} + c_{j}^{†} c_{i}) \sum_{i} ϵ_{i} c_{i}^{†} c_{i}

The single particle hamiltonian in 1d reads

H = [\begin{matrix} V_{1} & - t & 0 & 0 & 0 & 0 \\ - t & V_{2} & - t & 0 & 0 & 0 \\ 0 & - t & V_{3} & - t & 0 & 0 \\ 0 & 0 & - t & \dots & - t & 0 \\ 0 & 0 & 0 & - t & \dots & - t \\ 0 & 0 & 0 & 0 & - t & V_{L} \end{matrix}]

For simplicity we set the hopping $t = 1$ . The disorder are iid random variables drawn, uniformly from the box $(- \frac{W}{2}, \frac{W}{2})$ .

The final goal is to study the statistical properties of eigensystem

H ψ = ϵ ψ, with \sum_{n} | ψ_{n} |^{2} = 1

Density of states: In 1d the dispersion relation is $ϵ (k) = - 2 \cos_{k}, k \in (- π, π), - 2 < ϵ (k) < 2$ and the density of states is

ρ (ϵ) = \int_{- π}^{π} \frac{d k}{2 π} δ (ϵ - ϵ (k)) = \frac{1}{π} \frac{1}{\sqrt{4 - ϵ^{2}}} f o r ϵ \in (- 2, 2)

@@ Line 20: / Line 20: @@
 </math></center>
-For simplicity we set the hopping <math>t=1 </math>. The disorder are iid random variables drawn, uniformly from the box <math>(-\frac{W}{2},\frac{W}{2}</math>.
+For simplicity we set the hopping <math>t=1 </math>. The disorder are iid random variables drawn, uniformly from the box <math>(-\frac{W}{2},\frac{W}{2})</math>.
 The final goal is to study the statistical properties of eigensystem
@@ Line 26: / Line 26: @@
   H \psi=\epsilon \psi, \quad \text{with} \sum_n |\psi_n|^2=1
 </math></center>
+<Strong> Density of states: </Strong>In 1d the dispersion relation is
+<math> \epsilon(k) = -2 \cos_k,  k \in  (-\pi, \pi), -2<\epsilon(k)< 2 </math>  and the density of states is
+<center><math>
+\rho(\epsilon) =\int_{-\pi}^\pi \frac{d k}{2 \pi} \delta(\epsilon-\epsilon(k))=\frac{1}{\pi } \frac{1}{\sqrt{4-\epsilon^2}} \quad for \epsilon \in (-2,2)</math></center>

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Anderson model (tight bindind model)

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Anderson model (tight bindind model)

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