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Magnetoelectric coupling, efficiency, and voltage gain effect in piezoelectric-piezomagnetic laminate composites

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Frontiers of Ferroelectricity

Abstract

The magnetoelectric (ME) effect of piezoelectric-magnetostrictive laminate composites, which is a product tensor, has been studied. Based on piezoelectric and piezomagnetic constituent equations, the longitudinal-mode vibration and equivalent circuits have been derived. The effective magnetoelectric coupling coefficient, voltage-gain, and output efficiency have been determined. Our results show: (i) that there is an extreme high voltage gain effect of >260 under resonance drive: the induced ME voltage is much higher than the input voltage to the coils for magnetic excitation; (ii) that there is an optimum ratio of the piezoelectric to piezomagnetic layer thicknesses, which results in maximum effective magnetoelectric coupling; and (iii) that the maximum output efficiency of magnetoelectric laminate at resonance drive is ∼98%, if eddy currents are neglected. This high ME voltage gain effect offers potential for power transformer applications

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Authors and Affiliations

  1. Department of Materials Science & Engineering, Virginia Tech, Blacksburg, VA, 24061

    Shuxiang Dong, Jie-Fang Li & D. Viehland

Authors
  1. Shuxiang Dong
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  2. Jie-Fang Li
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  3. D. Viehland
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Dong, S., Li, JF., Viehland, D. (2006). Magnetoelectric coupling, efficiency, and voltage gain effect in piezoelectric-piezomagnetic laminate composites. In: Frontiers of Ferroelectricity. Springer, Boston, MA. https://doi.org/10.1007/978-0-387-38039-1_9

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