Large voltage-induced magnetic anisotropy change in a few atomic layers of iron

Maruyama, Toshisuke; Shiota, Yoichi; Nozaki, Takayuki; Ohta, Kengo; Toda, Naohiro; Mizuguchi, Masaki; Tulapurkar, Ashwin; Shinjo, Teruya; Shiraishi, Masashi; Mizukami, Shigemi; Ando, Yumiko; Suzuki, Y.

doi:10.1038/nnano.2008.406

Cited by 1,225 publications

(1,042 citation statements)

References 27 publications

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“…In ultrathin FePt films, they found a change of the coercivity of 4.5 % under the application of electric 1 Introduction fields. A Japanese group found large changes in the anisotropy of magnetic thin films in TMR junctions under application of high electric fields [12]. A bistable toggle switching of the magnetization direction between two bistable orientations has been reported very recently by the same group [13].…”

Section: Introductionmentioning

confidence: 95%

“…It was claimed that the electric field changed the number of unpaired d-electrons in the surface and thus affected the magnetic properties. The next step towards a possible application of MEC in high-efficiency memory devices was made in the group of Y. Suzuki: a change of the magnetic anisotropy by 40 % induced by an electric field in a Fe/MgO junction was observed in 2009 by Maruyama et al [12] (see Fig. 2.6b)).…”

Section: Magnetoelectric Couplingmentioning

confidence: 99%

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Magnetoelectric coupling at metal surfaces

et al. 2010

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Section: Introductionmentioning

confidence: 95%

Section: Magnetoelectric Couplingmentioning

confidence: 99%

Magnetoelectric coupling at metal surfaces

et al. 2010

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“…7) or an electric field can modify antiferromagnetic order (BiFeO 3 ) [8][9][10] . There are few ferromagnetic piezoelectric materials 11 in which to attempt voltage-driven changes in magnetization, but the magnetization of thin ferromagnetic films may be electrically modified via strain from piezoelectric substrates (BaTiO 3 19 ; or via the occupation of 3d orbitals in ultra-thin Fe films 20 .…”

Section: Between Ferroelectricmentioning

confidence: 99%

“…Demonstrating electrical control of coercivity 19,24 , exchange bias 25,26 or magnetic anisotropy 20,27 is insufficient because, respectively, an electrically addressable coercivity is inextricably linked with an applied magnetic field; because exchange bias is an interfacial phenomenon that cannot readily drive magnetization reversal throughout a film of significant thickness; and because no new magnetic anisotropy axis can lie more than 901 from the anisotropy axis along which the local magnetization initially lies. It has been suggested that this latter challenge may be overcome by applying a suitable sequence of normal stresses near the pre-existing magnetic anisotropy axes of a small homogeneously magnetized Stoner-Wohlfarth particle 28,29 , but this has not been experimentally realised.…”

Section: Between Ferroelectricmentioning

confidence: 99%

Non-volatile electrically-driven repeatable magnetization reversal with no applied magnetic field

et al. 2013

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Repeatable magnetization reversal under purely electrical control remains the outstanding goal in magnetoelectrics. Here we use magnetic force microscopy to study a commercially manufactured multilayer capacitor that displays strain-mediated coupling between magnetostrictive Ni electrodes and piezoelectric BaTiO 3 -based dielectric layers. In an electrode exposed by polishing approximately normal to the layers, we find a perpendicularly magnetized feature that exhibits non-volatile electrically driven repeatable magnetization reversal with no applied magnetic field. Using micromagnetic modelling, we interpret this nominally full magnetization reversal in terms of a dynamic precession that is triggered by strain from voltage-driven ferroelectric switching that is fast and reversible. The anisotropy field responsible for the perpendicular magnetization is reversed by the electrically driven magnetic switching, which is, therefore, repeatable. Our demonstration of non-volatile magnetic switching via volatile ferroelectric switching may inspire the design of fatigue-free devices for electric-write magnetic-read data storage.

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“…11 A strong effect of applied electric field on the interface MCA was demonstrated for the Fe/MgO (001) interfaces. 12 Magnetic easy axis manipulation by electric field was also achieved in the (Ga,Mn)As magnetic semiconductor. 13 Theoretically, the electric field effect on the MCA was investigated for various free-standing magnetic metal films 10,14-17 and Fe/MgO interfaces.…”

mentioning

confidence: 99%

Ferroelectric Control of Magnetocrystalline Anisotropy at Cobalt/Poly(vinylidene fluoride) Interfaces

et al. 2012

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Electric field control of magnetization is one of the promising avenues for achieving high-density energy-efficient magnetic data storage. Ferroelectric materials can be especially useful for that purpose as a source of very large switchable electric fields when interfaced with a ferromagnet. Organic ferroelectrics, such as poly(vinylidene fluoride) (PVDF), have an additional advantage of being weakly bonded to the ferromagnet, thus minimizing undesirable effects such as interface chemical modification and/or strain coupling. In this work we use first-principles density functional calculations of Co/PVDF heterostructures to demonstrate the effect of ferroelectric polarization of PVDF on the interface magnetocrystalline anisotropy that controls the magnetization orientation. We show that switching of the polarization direction alters the magnetocrystalline anisotropy energy of the adjacent Co layer by about 50%, driven by the modification of the screening charge induced by ferroelectric polarization. The effect is reduced with Co oxidation at the interface due to quenching the interface magnetization. Our results provide a new insight into the mechanism of the magnetoelectric coupling at organic ferroelectric/ferromagnet interfaces and suggest ways to achieve the desired functionality in practice.

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Large voltage-induced magnetic anisotropy change in a few atomic layers of iron

Cited by 1,225 publications

References 27 publications

Magnetoelectric coupling at metal surfaces

Magnetoelectric coupling at metal surfaces

Non-volatile electrically-driven repeatable magnetization reversal with no applied magnetic field

Ferroelectric Control of Magnetocrystalline Anisotropy at Cobalt/Poly(vinylidene fluoride) Interfaces

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