Enhanced Quantum Metric due to Vacancies in Graphene
Quentin Marsal, Annica M. Black‐Schaffer
Abstract
Random vacancies in a graphene monolayer induce defect states that are known to form a narrow impurity band centered around zero energy at half filling. We use a space-resolved formulation of the quantum metric and establish a strong enhancement of the electronic correlations in this impurity band. The enhancement is primarily due to strong correlations between pairs of vacancies situated on different sublattices at anomalously large spatial distances. We trace the strong enhancement to both the multifractal vacancy wave functions, which ties the system exactly at the Anderson insulator transition for all defect concentrations, and preserving the chiral symmetry.
Topics & Concepts
Condensed matter physicsGrapheneMultifractal systemVacancy defectPhysicsImpurityMaterials scienceQuantum mechanicsFractalMathematicsMathematical analysisGraphene research and applicationsQuantum and electron transport phenomenaTopological Materials and Phenomena