Litcius/Paper detail

Ferroelectricity-Driven Phonon Berry Curvature and Nonlinear Phonon Hall Transports

Jino Im, Choong H. Kim, Hosub Jin

2022Nano Letters10 citationsDOI

Abstract

Berry curvature (BC) governs topological phases of matter and generates anomalous transport. When a magnetic field is applied, phonons can acquire BC indirectly through spin-lattice coupling, leading to a linear phonon Hall effect. Here, we show that polar lattice distortion directly couples to a phonon BC dipole, which causes a switchable nonlinear phonon Hall effect. In a SnS monolayer, the in-plane ferroelectricity induces a phonon BC and leads to the phononic version of the nonvolatile BC memory effect. As a new type of ferroelectricity-phonon coupling, the phonon Rashba effect emerges and opens a mass gap in tilted Weyl phonon modes, resulting in a large phonon BC dipole. Furthermore, our ab initio non-equilibrium molecular dynamics simulations reveal that nonlinear phonon Hall transport occurs in a controllable manner via ferroelectric switching. The ferroelectricity-driven phonon BC and corresponding nonlinear phonon transports provide a novel scheme for constructing topological phononic transport/memory devices.

Topics & Concepts

PhononCondensed matter physicsBerry connection and curvatureFerroelectricityDipolePhysicsMaterials scienceQuantum mechanicsGeometric phaseDielectricTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsGraphene research and applications