Litcius/Paper detail

Monte Carlo study of the pseudogap and superconductivity emerging from quantum magnetic fluctuations

Weilun Jiang, Yuzhi Liu, Avraham Klein, Yuxuan Wang, Kai Sun, Andrey V. Chubukov, Zi Yang Meng

2022Nature Communications23 citationsDOIOpen Access PDF

Abstract

superconductors, remains one of the greatest puzzles in condensed matter physics. One possible mechanism is fermionic incoherence, which near a quantum critical point allows pair formation but suppresses superconductivity. Employing quantum Monte Carlo simulations of a model of itinerant fermions coupled to ferromagnetic spin fluctuations, represented by a quantum rotor, we report numerical evidence of pseudogap behavior, emerging from pairing fluctuations in a quantum-critical non-Fermi liquid. Specifically, we observe enhanced pairing fluctuations and a partial gap opening in the fermionic spectrum. However, the system remains non-superconducting until reaching a much lower temperature. In the pseudogap regime the system displays a "gap-filling" rather than "gap-closing" behavior, similar to the one observed in cuprate superconductors. Our results present direct evidence of the pseudogap state, driven by superconducting fluctuations.

Topics & Concepts

PseudogapPhysicsCondensed matter physicsPairingSuperconductivityQuantum Monte CarloCuprateQuantum critical pointHubbard modelQuantum fluctuationSpin (aerodynamics)Monte Carlo methodQuantumQuantum phase transitionQuantum mechanicsPhase transitionMathematicsThermodynamicsStatisticsPhysics of Superconductivity and MagnetismAdvanced Condensed Matter PhysicsMagnetic and transport properties of perovskites and related materials
Monte Carlo study of the pseudogap and superconductivity emerging from quantum magnetic fluctuations | Litcius