Litcius/Paper detail

Voltage‐Controlled Deblocking of Magnetization Reversal in Thin Films by Tunable Domain Wall Interactions and Pinning Sites

Jonas Zehner, Ivan Soldatov, Sebastian Schneider, René Heller, Nasrin B. Khojasteh, Sandra Schiemenz, S. Fähler, Kornelius Nielsch, Rudolf Schäfer, Karin Leistner

2020Advanced Electronic Materials26 citationsDOIOpen Access PDF

Abstract

Abstract High energy efficiency of magnetic devices is crucial for applications such as data storage, computation, and actuation. Redox‐based (magneto‐ionic) voltage control of magnetism is a promising room‐temperature pathway to improve energy efficiency. However, for ferromagnetic metals, the magneto‐ionic effects studied so far require ultrathin films with tunable perpendicular magnetic anisotropy or nanoporous structures for appreciable effects. This paper reports a fully reversible, low voltage‐induced collapse of coercivity and remanence by redox reactions in iron oxide/iron films with uniaxial in‐plane anisotropy. In the initial iron oxide/iron films, Néel wall interactions stabilize a blocked state with high coercivity. During the voltage‐triggered reduction of the iron oxide layer, in situ Kerr microscopy reveals inverse changes of coercivity and anisotropy, and a coarsening of the magnetic microstructure. These results confirm a magneto‐ionic deblocking mechanism, which relies on changes of the Néel wall interactions, and of the microstructural domain‐wall‐pinning sites. With this approach, voltage‐controlled 180° magnetization switching with high energy‐efficiency is achieved. It opens up possibilities for developing magnetic devices programmable by ultralow power and for the reversible tuning of defect‐controlled materials in general.

Topics & Concepts

CoercivityMaterials scienceRemanenceMagnetic anisotropyDomain wall (magnetism)FerromagnetismMagnetic domainGeomagnetic reversalMagnetismMagnetizationCondensed matter physicsNuclear magnetic resonanceOptoelectronicsMagnetic fieldPhysicsQuantum mechanicsMagnetic properties of thin filmsNanoporous metals and alloysCharacterization and Applications of Magnetic Nanoparticles