Quantum Phase diagrams and transitions for Chern topological insulators
Abstract
Topological invariants such as Chern classes are by now a standard way to classify topological phases. Varying systems in a family leads to phase diagrams, where the Chern classes may jump when crossingn a critical locus. These systems appear naturally when considering slicing of higher dimensional systems or when considering systems with parameters. As the Chern classes are topological invariants, they can only change if the ``topology breaks down''. We give a precise mathematical formulation of this phenomenon and show that synthetically any phase diagram of Chern topological phases can be designed and realized by a physical system, using covering, aka.\ winding maps. Here we provide explicit families realizing arbitrary Chern jumps. The critical locus of these maps is described by the classical rose curves. These give a lower bond on the number of Dirac points in general that is sharp for 2-level systems. In the process, we treat several concrete models. In particular, we treat the lattices and tight--binding models, and show that effective winding maps can be achieved using $k$--th nearest neighbors. We give explicit formulas for a family of 2D lattices using imaginary quadratic field extensions and their norms. This includes the square, triangular, honeycomb and Kagome lattices