Litcius/Paper detail

Exciton-driven antiferromagnetic metal in a correlated van der Waals insulator

Carina A. Belvin, Edoardo Baldini, Ilkem Ozge Ozel, Dan Mao, Hoi Chun Po, Clifford J. Allington, Suhan Son, Beom Hyun Kim, Jonghyeon Kim, Inho Hwang, Jae Hoon Kim, Je-Geun Park, T. Senthil, Nuh Gedik

2021Nature Communications98 citationsDOIOpen Access PDF

Abstract

Abstract Collective excitations of bound electron-hole pairs—known as excitons—are ubiquitous in condensed matter, emerging in systems as diverse as band semiconductors, molecular crystals, and proteins. Recently, their existence in strongly correlated electron materials has attracted increasing interest due to the excitons’ unique coupling to spin and orbital degrees of freedom. The non-equilibrium driving of such dressed quasiparticles offers a promising platform for realizing unconventional many-body phenomena and phases beyond thermodynamic equilibrium. Here, we achieve this in the van der Waals correlated insulator NiPS 3 by photoexciting its newly discovered spin–orbit-entangled excitons that arise from Zhang-Rice states. By monitoring the time evolution of the terahertz conductivity, we observe the coexistence of itinerant carriers produced by exciton dissociation and a long-wavelength antiferromagnetic magnon that coherently precesses in time. These results demonstrate the emergence of a transient metallic state that preserves long-range antiferromagnetism, a phase that cannot be reached by simply tuning the temperature. More broadly, our findings open an avenue toward the exciton-mediated optical manipulation of magnetism.

Topics & Concepts

van der Waals forceQuasiparticleExcitonAntiferromagnetismCondensed matter physicsMagnonPhysicsBound stateMott insulatorPolaronElectronInsulator (electricity)SpinsMaterials scienceTerahertz radiationTopological insulatorPhase (matter)Chemical physicsCoupling (piping)Metal–insulator transitionDissociation (chemistry)Spin statesMetalSpin (aerodynamics)Effective mass (spring–mass system)DielectricFerromagnetism2D Materials and ApplicationsTopological Materials and PhenomenaOrganic and Molecular Conductors Research