Fibonacci-Modulation-Induced Multiple Topological Anderson Insulators

We uncover the emergence of multiple topological Anderson insulators (TAIs) in a 1D spin-orbit coupled (SOC) chain driven by Fibonacci modulation, transforming a trivial band structure into a cascade of topologically nontrivial phases. This intriguing phenomenon is marked by the appearance of zero-energy modes and transitions in the $\mathcal{Z}_2$ topological quantum number. Strikingly, as the SOC amplitude decreases, the number of TAI phases grows, a behavior intricately linked to the fractal structure of the energy spectrum induced by Fibonacci modulation. Unlike conventional TAI phases, which exhibit fully localized eigenstates, the wave functions in the Fibonacci-modulated TAI phases exhibit multifractal behavior. Furthermore, this model can be experimentally realized in a Bose-Einstein condensate along the momentum lattice, where its topological transitions and multifractal properties can be probed through quench dynamics. Our findings open new avenues for exploring exotic disorder-induced topological phases and their intricate multifractal nature.