Litcius/Paper detail

Designing strong and tunable magnetoelectric coupling in 2D trilayer heterostructures

Xin Jin, Andrew O’Hara, Yuyang Zhang, Shixuan Du, Sokrates T. Pantelides

20222D Materials16 citationsDOI

Abstract

Abstract The quest for electric-field control of nanoscale magnetic states such as skyrmions, which would impact the field of spintronics, has led to a challenging search for multiferroic materials or structures with strong magnetoelectric coupling and efficient electric-field control. Here we report a theoretical prediction that such phenomena can be realized in two-dimensional (2D) bilayer FE/PMM and trilayer FE/PMM/FE heterostructures (two-terminal and three-terminal devices), where FE is a 2D ferroelectric and PMM is a polar magnetic metal with strong spin–orbit coupling. Such a PMM has strong Dzyaloshinskii-Moriya interactions (DMI) that can generate skyrmions, while the FE can generate strong magnetoelectric coupling through polarization-polarization interactions. In trilayer heterostructures, contact to the metallic PMM layer enables multiple polarization configurations for electric-field control of skyrmions. We report density-functional-theory calculations for particular material choices that demonstrate the effectiveness of these arrangements, with the key driver being the polarization-polarization interactions between the PMM and FE layers. The present findings provide a method to achieve strong magnetoelectric coupling in the 2D limit and a new perspective for the design of related spintronics.

Topics & Concepts

SpintronicsSkyrmionCondensed matter physicsHeterojunctionFerroelectricityPolarization (electrochemistry)Electric fieldMultiferroicsMagnetoelectric effectMaterials sciencePolarization densityCoupling (piping)Magnetic fieldOptoelectronicsFerromagnetismPhysicsMagnetizationDielectricChemistryQuantum mechanicsPhysical chemistryMetallurgyMultiferroics and related materials2D Materials and ApplicationsFerroelectric and Piezoelectric Materials