Low-Voltage Magnetoelectric Coupling in Membrane Heterostructures

S. Lindemann (1); J. Irwin (2); G.-Y. Kim (3); B. Wang (4); K. Eom; (1); J. J. Wang (4); J. M. Hu (1); L.Q. Chen (4); S. Y. Choi (3); C. B. Eom; (1); M. S. Rzchowski (2) ((1) University of Wisconsin-Madison Dept. of Mat.; Sci.; Eng.; (2) University of Wisconsin-Madison Dept. of Physics; (3); Pohang University of Science; Technology Dept. of Mat. Sci.; Eng.; (4); Pennsylvania State University Dept. of Mat. Sci.; Eng.)

arXiv:2110.05581·cond-mat.mtrl-sci·October 13, 2021·1 cites

Low-Voltage Magnetoelectric Coupling in Membrane Heterostructures

S. Lindemann (1), J. Irwin (2), G.-Y. Kim (3), B. Wang (4), K. Eom, (1), J. J. Wang (4), J. M. Hu (1), L.Q. Chen (4), S. Y. Choi (3), C. B. Eom, (1), M. S. Rzchowski (2) ((1) University of Wisconsin-Madison Dept. of Mat., Sci., Eng.

PDF

Open Access

TL;DR

This study demonstrates low-voltage magnetoelectric coupling in freestanding PMN-PT/Ni heterostructures, enabling efficient magnetic control with minimal voltage, advancing low-power multifunctional device technology.

Contribution

First demonstration of low-voltage ME coupling in all-thin-film membrane heterostructures using anisotropic strains from (011) PMN-PT.

Findings

01

Achieved 90-degree Ni magnetization rotation with 3V bias

02

Removed substrate clamping to enhance piezoelectric response

03

Clarified membrane response via microscopy and simulations

Abstract

Strain-mediated magnetoelectric (ME) coupling in ferroelectric (FE) / ferromagnetic (FM) heterostructures offers a unique opportunity for both fundamental scientific research and low power multifunctional devices. Relaxor-ferroelectrics, like (1-x)Pb(Mg1/3Nb2/3)O3-(x)PbTiO3 (PMN-xPT), are ideal FE layer candidates due to their giant piezoelectricity. But thin films of PMN-PT suffer from substrate clamping which substantially reduces piezoelectric in-plane strains. Here we present the first demonstration of low voltage ME coupling in an all-thin-film heterostructure which utilizes the anisotropic strains induced by the (011) orientation of PMN-PT. We completely remove PMN-PT films from their substrate and couple with FM Ni overlayers to create membrane PMN-PT/Ni heterostructures showing 90 degree Ni magnetization rotation with 3V PMN-PT bias, much less than the bulk PMNPT ~100V…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.

Taxonomy

TopicsMultiferroics and related materials · Ferroelectric and Piezoelectric Materials · Underwater Acoustics Research