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Explaining the pseudogap through damping and antidamping on the Fermi surface by imaginary spin scattering

Friedrich Krien, Paul Worm, Patrick Chalupa-Gantner, A. Toschi, Karsten Held

2022Communications Physics34 citationsDOIOpen Access PDF

Abstract

Abstract The mechanism of the pseudogap observed in hole-doped cuprates remains one of the central puzzles in condensed matter physics. We analyze this phenomenon via a Feynman-diagrammatic inspection of the Hubbard model. Our approach captures the pivotal interplay between Mott localization and Fermi surface topology beyond weak-coupling spin fluctuations, which would open a spectral gap near hot spots. We show that strong coupling and particle-hole asymmetry trigger a very different mechanism: a large imaginary part of the spin-fermion vertex promotes damping of antinodal fermions and, at the same time, protects the nodal Fermi arcs (antidamping). Our analysis naturally explains puzzling features of the pseudogap observed in experiments, such as Fermi arcs being cut off at the antiferromagnetic zone boundary and the subordinate role of hot spots.

Topics & Concepts

PseudogapFermi surfaceCondensed matter physicsThe ImaginaryFermi Gamma-ray Space TelescopeSpin (aerodynamics)PhysicsScatteringSurface (topology)Quantum mechanicsSuperconductivityMathematicsPsychotherapistGeometryThermodynamicsPsychologyCupratePhysics of Superconductivity and MagnetismQuantum and electron transport phenomenaTopological Materials and Phenomena
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