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Global phase diagram of two-dimensional dirty hyperbolic Dirac liquids

Published 4 Dec 2025 in cond-mat.mes-hall, cond-mat.dis-nn, cond-mat.stat-mech, and hep-th | (2512.05109v1)

Abstract: Within the framework of the canonical nearest-neighbor tight-binding model for spinless fermions, a family of two-dimensional bipartite hyperbolic lattices hosts massless Diraclike excitations near half-filling with the iconic vanishing density of states (DOS) near zero energy. We show that a collection of such ballistic quasiparticles remains stable against sufficiently weak pointlike charge impurities, a feature captured by the vanishing average [$ρ{a}(0)$] and typical [$ρ{t}(0)$] DOS at zero energy, computed by employing the kernel polynomial method in sufficiently large ${ 10, 3}$ hyperbolic lattices (Schläfli symbol) with more than $108$ and $105$ sites, respectively, with open boundary conditions. However, at moderate disorder the system enters a metallic state via a continuous quantum phase transition where both $ρ{a}(0)$ and $ρ{t}(0)$ become finite. With increasing strength of disorder, ultimately an Anderson insulator sets in, where only $ρ{t}(0) \to 0$. The resulting phase diagram for dirty Dirac fermions living on a hyperbolic space solely stems from the background negative spatial curvature, as confirmed from the vanishing $ρ{t}(0)$ for arbitrarily weak disorder on honeycomb lattices, fostering relativistic fermions on a flatland, as the thermodynamic limit is approached.

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