Non-Bloch Band Theory for 2D Geometry-Dependent Non-Hermitian Skin Effect (2506.22743v1)

Abstract: The non-Hermitian skin effect (NHSE), characterized by boundary-localized eigenstates under open boundary conditions, represents the key feature of the non-Hermitian lattice systems. Although the non-Bloch band theory has achieved success in depicting the NHSE in one-dimensional (1D) systems, its extension to higher dimensions encounters a fundamental hurdle in the form of the geometry-dependent skin effect (GDSE), where the energy spectra and the boundary localization of the eigenstates rely on the lattice geometry. In this work, we establish the non-Bloch band theory for two-dimensional (2D) GDSE, by introducing a strip generalized Brillouin zone (SGBZ) framework. Through taking two sequential 1D thermodynamic limits, first along a major axis and then along a minor axis, we construct geometry-dependent non-Bloch bands, unraveling that the GDSE originates from the competition between incompatible SGBZs. Based on our theory, we derive for the first time a crucial sufficient condition for the GDSE: the non-Bloch dynamical degeneracy splitting of SGBZ eigenstates, where a continuous set of degenerate complex momenta breaks down into a discrete set. Moreover, our SGBZ formulation reveals that the Amoeba spectrum contains the union of all possible SGBZ spectra, which bridges the gap between the GDSE and the Amoeba theory. The proposed SGBZ framework offers a universal roadmap for exploring non-Hermitian effects in 2D lattice systems, opening up new avenues for the design of novel non-Hermitian materials and devices with tailored boundary behaviors.