Voltage control of magnetism (VCM) is attracting increasing interest and exciting significant research activity driven by its profound physics and enormous potential for application. This review article aims to provide a comprehensive review of recent progress in VCM in different thin films. We first present a brief summary of the modulation of magnetism by electric fields and describe its discovery, development, classification, mechanism, and potential applications. In the second part, we focus on the classification of VCM from the viewpoint of materials, where both the magnetic medium and dielectric gating materials, and their influences on magnetic modulation efficiency are systematically described. In the third part, the nature of VCM is discussed in detail, including the conventional mechanisms of charge, strain, and exchange coupling at the interfaces of heterostructures, as well as the emergent models of orbital reconstruction and electrochemical effect. The fourth part mainly illustrates the typical performance characteristics of VCM, and discusses, in particular, * Corresponding author. Tel: +86-10-62781275; fax: +86-10-62771160 E-mail address: songcheng@mail.tsinghua.edu.cn † Present at Max-Planck Institute of Microstructure Physics, Weinberg 2, D-06120Halle, Germany 2 its promising application for reducing power consumption and realizing high-density memory in several device configurations. The present review concludes with a discussion of the challenges and future prospects of VCM, which will inspire more in-depth research and advance the practical applications of this field.
We investigate the current-induced switching of the Néel order in NiO(001)/Pt heterostructures, which is manifested electrically via the spin Hall magnetoresistance. Significant reversible changes in the longitudinal and transverse resistances are found at room temperature for a current threshold lying in the range of 10^{7} A/cm^{2}. The order-parameter switching is ascribed to the antiferromagnetic dynamics triggered by the (current-induced) antidamping torque, which orients the Néel order towards the direction of the writing current. This is in stark contrast to the case of antiferromagnets such as Mn_{2}Au and CuMnAs, where fieldlike torques induced by the Edelstein effect drive the Néel switching, therefore resulting in an orthogonal alignment between the Néel order and the writing current. Our findings can be readily generalized to other biaxial antiferromagnets, providing broad opportunities for all-electrical writing and readout in antiferromagnetic spintronics.
A combination of resistive switching and magnetic modulation gives rise to the integration of room temperature ferromagnetism (spin) and electrical properties (charge) into a simple Pt/Co:ZnO/Pt structure due to the formation of oxygen vacancy-based conductive filaments. This is promising for broadening the applications of random access memories to encode quaternary information.
Dynamic formation/rupture processes of metallic filament
have been
clarified in solid electrolyte- and oxide-based resistive memory devices,
whereas they remain exclusive in organic ones. Here we report these
dynamic processes in Cu/poly (3-hexylthiophene):[6,6]-phenyl C61-butyric
acid methyl ester/indium–tin oxide (ITO) structure, which exhibits
a typical bipolar resistive
switching effect. Under illumination, an open circuit voltage of −0.15
V exists in high-resistance state, yet it vanishes in low-resistance
state owing to the emergence of Cu filament. By combining the symmetry
of current–voltage curves with corresponding energy band diagrams
in different resistance
states, it is demonstrated that the Cu filament grows from Cu/organics
interface, ends at organics/ITO interface, and ruptures near organics/ITO
interface. This work might advance the insight into resistive switching
mechanisms in organic-based resistive memories.
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