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Strong reduction of the coercivity by a surface acoustic wave in an out-of-plane magnetized epilayer

Inverse magnetostriction is the effect by which magnetization can be changed upon application of stress/strain. A strain modulation may be created electrically by exciting interdigitated transducers to generate surface acoustic waves (SAWs). Hence SAWs appear as a possible route towards induction-free undulatory magnetic data manipulation. Here we demonstrate experimentally on an out-of-plane magnetostrictive layer a reduction of the coercive field of up to 60$\%$ by a SAW, over millimetric distances. A simple model shows that this spectacular effect can be partly explained by the periodic lowering of the strain-dependent domain nucleation energy by the SAW. This proof of concept was done on (Ga,Mn)(As,P), a magnetic semiconductor in which the out-of-plane magnetic anisotropy can be made very weak by epitaxial growth; it should guide material engineering for all-acoustic magnetization switching.

preprint2016arXivOpen access
Laura ThevenardIbrahima Sock CamaraJean-Yves PrieurPauline RovillainAristide LemaîtreCatherine GourdonJean-Yves Duquesne
cond-mat.mtrl-sci
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Open access7 authors1 topic
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Laura ThevenardIbrahima Sock CamaraJean-Yves PrieurPauline RovillainAristide LemaîtreCatherine GourdonJean-Yves Duquesne

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