Topological Origin of Andreev Flatland in UTe$_2$: Implication for Josephson STM Measurements

We propose the surface of topological superconductors as a platform for realizing two-dimensional flat bands, where electron interactions play a crucial role. The surface flat bands originate from topological features supported by two key mechanisms: (1) a trivial Chern number prevents the zero-energy states from merging into the continuum of the bulk spectrum, thereby ensuring their confinement within the superconducting gap; and (2) weak spin conservation allows the gap function to exhibit phase winding. As a consequence, the surface exhibits a remarkably high density of states at nearly zero energy. Such surface states are likely to be realized in the candidate topological superconductor UTe$_2$. Our results provide important insights into the interpretation of recent Josephson STM experiments on UTe$_2$.