Corner and Edge States in Topological Sierpinski Carpet Systems

Fractal lattices, with their self-similar and intricate structures, offer potential platforms for engineering physical properties on the nanoscale and also for realizing and manipulating high order topological insulator states in novel ways. Here we present a theoretical discussion on localized corner and edge states, as well as electronic properties emerging from topological phases in Sierpinski Carpet within a $\pi$-flux regime. A topological hopping parameter phase diagram is constructed from which different spatial localized states are identified following signatures of distinct fractal generations. The specific geometry and scaling properties of the fractal systems can guide the supported topological states types and their associated functionalities. A conductive device is proposed by coupling identical Sierpinski Carpet units providing transport response through projected edge states that carrier the details of the Sierpinski Carpet topology.