Publikation: Nonvolatile, reversible electric-field controlled switching of remanent magnetization in multifunctional ferromagnetic/ferroelectric hybrids
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In spin-mechanics, the magnetoelastic coupling in ferromagnetic/ferroelectric hybrid devices is exploited in order to realize an electric-voltage control of magnetization orientation. To this end, different voltage-induced elastic strain states are used to generate different magnetization orientations. In our approach, we take advantage of the hysteretic expansion and contraction of a commercial piezoelectric actuator as a function of electrical voltage to deterministically select one of two electro-remanent elastic strain states. We investigate the resulting magnetic response in a nickel thin film/piezoelectric actuator hybrid device at room temperature, using simultaneous magneto-optical Kerr effect and magnetotransport measurements. The magnetic properties of the hybrid can be consistently described in a macrospin model, i.e., in terms of a single magnetic domain. At zero external magnetic field, the magnetization orientation in the two electro-remanent strain states differs by 15°, which corresponds to a magnetoresistance change of 0.5%. These results demonstrate that the spin-mechanics scheme indeed enables a nonvolatile electrically read- and writable memory bit where the information is encoded in a magnetic property.
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BRANDLMAIER, Andreas, Stephan GEPRÄGS, Georg WOLTERSDORF, Rudolf GROSS, Sebastian T. B. GOENNENWEIN, 2011. Nonvolatile, reversible electric-field controlled switching of remanent magnetization in multifunctional ferromagnetic/ferroelectric hybrids. In: Journal of Applied Physics. American Institute of Physics (AIP). 2011, 110(4), 043913. ISSN 0021-8979. eISSN 1089-7550. Available under: doi: 10.1063/1.3624663BibTex
@article{Brandlmaier2011Nonvo-52640,
year={2011},
doi={10.1063/1.3624663},
title={Nonvolatile, reversible electric-field controlled switching of remanent magnetization in multifunctional ferromagnetic/ferroelectric hybrids},
number={4},
volume={110},
issn={0021-8979},
journal={Journal of Applied Physics},
author={Brandlmaier, Andreas and Geprägs, Stephan and Woltersdorf, Georg and Gross, Rudolf and Goennenwein, Sebastian T. B.},
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