Enhancing Magneto-Ionic Effects in Magnetic Nanostructured Films via Conformal Deposition of Nanolayers with Oxygen Acceptor/Donor Capabilities

Effective manipulation of the magnetic properties of nanostructured metallic alloys, exhibiting intergrain porosity (i.e., channels) and conformally coated with insulating oxide nanolayers, with an electric field is demonstrated. Nanostructured Co–Pt films are grown by electrodeposition (ED) and sub...

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Bibliographic Details
Published in:ACS applied materials & interfaces 2020-03, Vol.12 (12), p.14484-14494
Main Authors: Navarro-Senent, Cristina, Quintana, Alberto, Isarain-Chávez, Eloy, Weschke, Eugen, Yu, Pengmei, Coll, Mariona, Pellicer, Eva, Menéndez, Enric, Sort, Jordi
Format: Article
Language:English
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Summary:Effective manipulation of the magnetic properties of nanostructured metallic alloys, exhibiting intergrain porosity (i.e., channels) and conformally coated with insulating oxide nanolayers, with an electric field is demonstrated. Nanostructured Co–Pt films are grown by electrodeposition (ED) and subsequently coated with either AlO x or HfO x by atomic layer deposition (ALD) to promote magneto-ionic effects (i.e., voltage-driven ion migration) during electrolyte gating. Pronounced variations in coercivity (H C) and magnetic moment at saturation (m S) are found at room temperature after biasing the heterostructures. The application of a negative voltage results in a decrease of H C and an increase of m S, whereas the opposite trend is achieved for positive voltages. Although magneto-ionic phenomena are already observed in uncoated Co–Pt films (because of the inherent presence of oxygen), the ALD oxide nanocoatings serve to drastically enhance the magneto-ionic effects because of partially reversible oxygen migration, driven by voltage, across the interface between AlO x or HfO x and the nanostructured Co–Pt film. Co–Pt/HfO x heterostructures exhibit the most significant magneto-electric response at negative voltages, with an increase of m S up to 76% and a decrease of H C by 58%. The combination of a nanostructured magnetic alloy and a skinlike insulating oxide nanocoating is shown to be appealing to enhance magneto-ionic effects, potentially enabling electrolyte-gated magneto-ionic technology.
ISSN:1944-8244
1944-8252
DOI:10.1021/acsami.9b19363