Ionic control of magnetism in all-solid-state CoOx/yttria-stabilized zirconia heterostructures

Ionic control of magnetism in all-solid-state CoOx/yttria-stabilized zirconia heterostructures

Magneto-ionic gating, a procedure that enables the modulation of materials' magnetic properties by voltage-driven ion motion, offers alternative perspectives for emerging low-power magnetic storage and spintronic applications. Most previous studies in all-solid-state magneto-ionic systems have...

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Bibliographic Details
Published in:Applied physics letters Vol. 124; no. 20
Main Authors: Ma, Zheng, Tan, Zhengwei, Quintana, Alberto, Spasojevic, Irena, López-Pintó, Nicolau, Sánchez, Florencio, Fina, Ignasi, Herrero-Martín, Javier, Menéndez, Enric, Sort, Jordi
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 13-05-2024
Subjects:
Cobalt oxides
Dichroism
Electric fields
Electric potential
Electrons
Ferromagnetism
Heterostructures
Ion motion
Magnetic films
Magnetic properties
Magnetic storage
Magnetism
Power management
Room temperature
Solid state
Voltage
X ray absorption
Yttria-stabilized zirconia
Yttrium oxide
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Summary:Magneto-ionic gating, a procedure that enables the modulation of materials' magnetic properties by voltage-driven ion motion, offers alternative perspectives for emerging low-power magnetic storage and spintronic applications. Most previous studies in all-solid-state magneto-ionic systems have focused on the control of interfacial magnetism of ultrathin (i.e., 1–3 nm) magnetic films, taking advantage of an adjacent ionic conducting oxide, usually GdOx or HfOx, that transports functional ionic species (e.g., H+ or O2−). Here, we report on room-temperature OFF–ON ferromagnetism by solid-state magneto-ionics in relatively thick (25 nm) patterned CoOx films grown on an yttria-stabilized zirconia (YSZ) layer, which acts as a dielectric to hold electric field and as an O2− ion reservoir. Upon negatively biasing, O2− ions from the CoOx tend to migrate toward the YSZ gate electrode, leading to the gradual generation of magnetization (i.e., OFF-to-ON switching of a ferromagnetic state). X-ray absorption and magnetic circular dichroism studies reveal subtle changes in the electronic/chemical characteristics, responsible for the induced magnetoelectric effects in such all-oxide heterostructures. Recovery of the initial (virtually non-magnetic) state is achieved by application of a positive voltage. The study may guide future development of all-solid-state low-power CMOS-compatible magneto-ionic devices.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0206743