Higher-order Topological Knots and Nonreciprocal Dynamics in non-Hermitian lattices

In two dimensions, Hermitian lattices with non-zero Chern numbers and non-Hermitian lattices with a higher-order skin effect (HOSE) bypass the constraints of the Nielsen-Ninomiya "no-go" theorem at their one-dimensional boundaries. This allows the realization of topologically protected one-dimensional edge states with nonreciprocal dynamics. However, unlike the edge states of Chern insulators, the nonreciprocal edges of HOSE phases exist only at certain edges of the two-dimensional lattice, not all, leading to corner-localized states. In this work, we investigate the topological connections between these two systems and uncover novel non-Hermitian topological phases possessing "higher-order topological knots" (HOTKs). These phases arise from multiband topology protected by crystalline symmetries and host point-gap-protected nonreciprocal edge states that circulate around the entire boundary of the two-dimensional lattice. We show that phase transitions typically separate HOTK phases from "Complex Chern insulator" phases --non-Hermitian lattices with nonzero Chern numbers protected by imaginary line gaps in the presence of time-reversal symmetry.