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Topological Green’s Function Zeros in an Exactly Solved Model and Beyond

Steffen Bollmann, Chandan Setty, Urban F. P. Seifert, Elio J. König

2024Physical Review Letters13 citationsDOIOpen Access PDF

Abstract

The interplay of topological electronic band structures and strong interparticle interactions provides a promising path towards the constructive design of robust, long-range entangled many-body systems. As a prototype for such systems, we here study an exactly integrable, local model for a fractionalized topological insulator. Using a controlled perturbation theory about this limit, we demonstrate the existence of topological bands of zeros in the exact fermionic Green's function and show that in this model they do affect the topological invariant of the system, but not the quantized transport response. Close to (but prior to) the Higgs transition signaling the breakdown of fractionalization, the topological bands of zeros acquire a finite "lifetime." We also discuss the appearance of edge states and edge zeros at real space domain walls separating different phases of the system. This model provides a fertile ground for controlled studies of the phenomenology of Green's function zeros and the underlying exactly solvable lattice gauge theory illustrates the synergetic cross pollination between solid-state theory, high-energy physics, and quantum information science.

Topics & Concepts

PhysicsTopology (electrical circuits)Topological insulatorLattice (music)Quantum mechanicsMathematicsCombinatoricsAcousticsTopological Materials and PhenomenaQuantum many-body systemsAdvanced Condensed Matter Physics
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