Regulating oxygen ion transport at the nanoscale to enable highly cyclable magneto-ionic control of magnetism

Magneto-ionics refers to the control of magnetic properties of materials through voltage-driven ion motion. To generate effective electric fields, either solid or liquid electrolytes are utilized, which also serve as ion reservoirs. Thin solid electrolytes have difficulties to (i) withstand high ele...

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Detalles Bibliográficos
Autores: Tan, Zhengwei|||0000-0003-4142-0637, Ma, Zheng|||0000-0003-3655-1448, Fuentes-Rodríguez, Laura|||0000-0002-8799-2369, Liedke, Maciej Oskar|||0000-0001-7933-7295, Butterling, Maik|||0000-0003-3674-0767, Attallah, Ahmed|||0000-0002-7759-0315, Hirschmann, Eric, Wagner, Andreas|||0000-0001-7575-3961, Abad, Llibertat|||0000-0003-2637-8629, Casañ Pastor, Nieves|||0000-0003-2979-4572, Lopeandia, Aitor|||0000-0003-0566-8299, Menéndez, Enric|||0000-0003-3809-2863, Sort, Jordi|||0000-0003-1213-3639
Tipo de recurso: artículo
Fecha de publicación:2023
País:España
Institución:Universitat Autònoma de Barcelona
Repositorio:Dipòsit Digital de Documents de la UAB
Idioma:inglés
OAI Identifier:oai:ddd.uab.cat:273267
Acceso en línea:https://ddd.uab.cat/record/273267
https://dx.doi.org/urn:doi:10.1021/acsnano.3c01105
Access Level:acceso abierto
Palabra clave:Magneto-electricity
Voltage control of magnetism
Magneto-ionics
Transition metal oxide
Ion diffusion
Descripción
Sumario:Magneto-ionics refers to the control of magnetic properties of materials through voltage-driven ion motion. To generate effective electric fields, either solid or liquid electrolytes are utilized, which also serve as ion reservoirs. Thin solid electrolytes have difficulties to (i) withstand high electric fields without electric pinholes and (ii) maintain stable ion transport during long-term actuation. In turn, the use of liquid electrolytes can result in poor cyclability, thus limiting their applicability. Here we propose a nanoscale-engineered magneto-ionic architecture (comprising a thin solid electrolyte in contact with a liquid electrolyte), that drastically enhances cyclability while preserving sufficiently high electric fields to trigger ion motion. Specifically, we show that the insertion of a highly nanostructured (amorphous-like) Ta layer (with suitable thickness and electric resistivity) between a magneto-ionic target material (i.e., Co3O4) and the liquid electrolyte, increases magneto-ionic cyclability from < 30 cycles (when no Ta is inserted) to more than 800 cycles. Transmission electron microscopy together with variable energy positron annihilation spectroscopy reveal the crucial role of the generated TaOx interlayer as a solid-electrolyte (i.e., ionic conductor) that improves magneto-ionic endurance by proper tuning of the types of voltage-driven structural defects. The Ta layer is very effective in trapping oxygen and hindering O2- ions from moving into the liquid electrolyte, thus keeping O2- motion mainly restricted between Co3O4 and Ta when voltage of alternating polarity is applied. We demonstrate that this approach provides a suitable strategy to boost magneto-ionics by combining the benefits of solid and liquid electrolytes in a synergetic manner.