Electrostatically induced β-phase alignment in the PVDF/thermally annealed CoFe2O4/Ni magnetoelectric laminates

Polymer-based magnetoelectric (ME) composites are garnering increasing attention for developing functional devices in various electronic applications. In terms of polymer-based ME laminates, which comprise piezoelectric (PE) polymer films and magnetostrictive (MS) substrates, the contact interface b...

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Bibliographic Details
Published in:MRS bulletin 2024, Vol.49 (8), p.817-824
Main Authors: Noh, Byung-Il, Song, Manseong, Yang, Su Chul
Format: Article
Language:English
Subjects:
Alignment
Annealing
Applied and Technical Physics
Beta phase
Characterization and Evaluation of Materials
Chemistry and Materials Science
Cobalt
Cobalt ferrites
Crystallites
Electric contacts
Energy conversion efficiency
Energy Materials
Fluorides
Impact Article
Laminates
Magnetostriction
Materials Engineering
Materials Science
Multiphase
Nanotechnology
Nickel
Piezoelectricity
Polymer films
Polymers
Polyvinylidene fluorides
Sol-gel processes
Substrates
Vinylidene fluoride
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Summary:Polymer-based magnetoelectric (ME) composites are garnering increasing attention for developing functional devices in various electronic applications. In terms of polymer-based ME laminates, which comprise piezoelectric (PE) polymer films and magnetostrictive (MS) substrates, the contact interface between the phases significantly affects the ME response owing to a mechanical and electrical interaction. In this study, poly(vinylidene fluoride) (PVDF)-based ME laminates composed of annealed cobalt ferrite ( a -CFO)/nickel (Ni) ( a -CFO/Ni) MS substrate were designed to trigger electrostatically aligned electroactive β-phase crystalline within PE films. The Ni substrates were treated through sol-gel coating of CFO precursor solution followed by thermal annealing under various temperatures. Next, the PVDF solution was cast on the multiphase MS substrate to build PVDF/ a -CFO/Ni laminates with varying casting heights to investigate the effective distance for β-phase formation and alignment. Finally, for the ME laminates prepared with the lowest casting height, the highest ME coefficient of 1.24 mV/cm·Oe was observed, accompanied by a β-phase fraction of 91.7% and a crystallinity degree of 56.3% in the PE phase. It is particularly noteworthy that the prepared laminates exhibited ME voltage without an electrical poling process. This result was assumed to be because the effective alignment of β-phase crystallites was promoted by active electrostatic interaction between the phases owing to the negatively charged surface of a -CFO/Ni substrates. In summary, it has been demonstrated that surface-charged MS substrates have considerable potential to improve energy-conversion efficiency by raising the electroactive phase fraction and making the process more cost-effective without post-polarization treatment. Graphical abstract Impact statement Poly(vinylidene fluoride) (PVDF)/annealed cobalt ferrite/nickel (PVDF/ a -CFO/Ni) magnetoelectric (ME) laminates are designed to induce β-phase alignment. Multiphase annealed cobalt ferrite/nickel ( a -CFO/Ni) magnetostrictive (MS) substrates exhibit a negatively charged surface. The highest value is 91.7% for β-phase fraction induced by surface-modified MS substrates in PVDF/ a -CFO/Ni laminates. Investigation of the maximal ME response with self-bias effect in PVDF/ a -CFO/Ni laminates.
ISSN:0883-7694
1938-1425
DOI:10.1557/s43577-024-00686-w