Stability of the symmetry-protected topological phase and Ising transitions in a disordered U(1) quantum link model on a ladder

TL;DR

This study investigates the stability of the symmetry-protected topological phase and Ising transitions in a disordered U(1) quantum link model on a ladder, revealing robustness of certain phases against disorder through finite-size scaling and field-theoretic analysis.

Contribution

It demonstrates that the topological phase and Ising criticality in a disordered U(1) quantum link ladder are more robust than expected, surviving certain types of disorder.

Findings

Critical exponent ν=1 and central charge c=1/2 indicate Ising universality.

Transitions survive strong disorder affecting rung hoppings.

Topological phase persists under small disorder in ladder's legs.

Abstract

We revisit the U(1) quantum link model in a ladder geometry, finding, by finite-size scaling, that the critical exponent $\nu=1$ and the central charge $c=1/2$ are consistent with the Ising universality class for all phase transitions observed. A blind application of the Harris criterion would suggest that this criticality is lost in the presence of the disorder. It turns out not to be the case. For the disorder affecting ladder's rung hoppings only, we have found that the transitions survive disappearing only for quite strong disorder. The disorder in the ladder's legs destroys the nonzero mass phase criticality, while the symmetry-protected topological phase for zero mass survives a small disorder. The observed robustness against disorder is explained qualitatively using field-theoretic arguments.