Giant self-biased converse magnetoelectric effect in multiferroic heterostructure with single-phase magnetostrictive materials

Zhang, Jitao; Li, Ping; Wen, Yumei; He, Wei; Yang, Aichao; Wang, Decai; Yang, Chen; Lu, Caijiang

doi:10.1063/1.4900929

Cited by 20 publications

(12 citation statements)

References 26 publications

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“…In the absence of H dc a maximum a CME of 5 (mG cm)/V is achieved at B 1 mode. This is three orders of magnitude higher than the previously reported self-biased CME coefficient in laminate composite [19]. The R 1 mode and B 2 mode shows a self-biased a CME value of 1.8 and 1.2 (mG cm)/V respectively.…”

Section: Resonance Me Studiescontrasting

confidence: 47%

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Enhanced self-biased direct and converse magnetoelectric effect in Pb(In1/2Nb1/2)O3–PbTiO3/NiFe2O4 bi-layer laminate composite

Kumar

Ramesh

Subramanian

2015

J Mater Sci: Mater Electron

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The direct magnetoelectric (DME) effect and converse magnetoelectric (CME) effect are investigated in bi-layer ferroelectric [0.65 Pb(In 1/2 Nb 1/2 )O 3 -0.35 PbTiO 3 ]-ferrite [NiFe 2 O 4 ] laminate composite prepared by epoxy bonding. The magnetoelectric (ME) properties of bi-layer composite is studied at low frequency (1 kHz) and at electromechanical resonance frequencies under external bias field (H dc ). The laminate composite shows a DME coefficient (a DME ) and CME coefficient (a CME ) of 103 mV/ (cm Oe) and 0.04 (mG cm)/V respectively at 1 kHz with a H dc of 110 Oe. Moreover the a DME and a CME shows nonzero value in the absence of external bias field, which signifies the presence of self-biased ME effect in this laminate composite. Under resonance condition, ME coupling enhanced two orders of magnitude compared to low frequency value. A large self biased a DME of 8 V/(cm Oe) and a CME of 5 (mG cm)/V is achieved at electromechanical resonance.

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Section: Resonance Me Studiescontrasting

confidence: 47%

“…The hysteresis and remanent magnetization in the ferromagnetic layer of the ME composite give rise to ME coefficient in the absence of external bias field in these structures. But there are only very few studies on self-biased CME effect and the reported values are low [14,19].…”

Section: Introductionmentioning

confidence: 98%

Enhanced self-biased direct and converse magnetoelectric effect in Pb(In1/2Nb1/2)O3–PbTiO3/NiFe2O4 bi-layer laminate composite

Kumar

Ramesh

Subramanian

2015

J Mater Sci: Mater Electron

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“…These values correspond to a remanent magnetoelectric coupling at zero bias field µ 0 H, which is related to the hysteretic magnetic behavior and the strong remanent magnetization [49,71]. This is truly encouraging for the dynamic CME self-biased potential of FeGa/PMN-PZT in applications, which is revealed in measurements that assess the magnetization change under an alternating AC electric field superimposed to a DC magnetic bias field µ 0 H (yielding a non-zero remanent CME(µ 0 H) at µ 0 H = 0) [31,[67][68][69].…”

Section: Magnetoelectric Coefficient α Cmementioning

confidence: 66%

“…FeGa has been the choice of magnetostrictive material for many studies, suggesting versatile proposals for the development of multifunctional devices exploiting both DME [56][57][58] and CME effects [9,19,24,[59][60][61][62][63][64][65][66]. Among these studies some have reported the dynamic self-biased effect, also called remanent CME, which is a desirable property recently seeked to control the magnetization using an electric field in ME devices without the need for the assistance of an external biasing magnetic field [31,49,[67][68][69][70][71]. Self-biased CME is indeed important for lower-energy consumption and more compact ME devices.…”

Section: Introductionmentioning

confidence: 99%

Electrical manipulation of magnetic anisotropy in a Fe$_{81}$Ga$_{19}$/PMN-PZT magnetoelectric multiferroic composite

Jahjah,

Jay,

Grand

et al. 2019

Preprint

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“…The device concepts that have recently emerged using electric field control of magnetization switching − provide an alternative route to achieve fast and high-density information storage with very low energy consumption . A multiferroic heterostructure composed of FM and ferroelectric (FE) materials is well-suited for high-speed, low-power, and ultradense device structures. − So far, there have been three main methods available for the electric field control of magnetism in FM/FE multiferroic heterostructures, including (i) strain-mediated magnetoelastic coupling with the piezostrain of the FE transferred to the FM layer, , (ii) exchange bias-mediated interaction, , and (iii) manipulation of charge carrier density. , Among them, the electric field control of magnetism through strain-mediated coupling in FM/FE multiferroic heterostructures has become a hot topic due to the availability of a variety of room-temperature FM and FE materials and the remarkable magnetoelectric effects . The strain is induced by applying an electric field to the FE layer via the piezoelectric effect, and the induced strain is then transferred to the FM layer, altering the magnetization via magnetostriction.…”

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confidence: 99%

Energy Efficient All-Electric-Field-Controlled Multiferroic Magnetic Domain-Wall Logic

Singh

Yang

et al. 2023

Nano Lett.

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Magnetic domain wall (DW)-based logic devices offer numerous opportunities for emerging electronics applications allowing superior performance characteristics such as fast motion, high density, and nonvolatility to process information. However, these devices rely on an external magnetic field, which limits their implementation; this is particularly problematic in large-scale applications. Multiferroic systems consisting of a piezoelectric substrate coupled with ferromagnets provide a potential solution that provides the possibility of controlling magnetization through an electric field via magnetoelastic coupling. Strain-induced magnetization anisotropy tilting can influence the DW motion in a controllable way. We demonstrate a method to perform all-electrical logic operations using such a system. Ferromagnetic coupling between neighboring magnetic domains induced by the electric-field-controlled strain has been exploited to promote noncollinear spin alignment, which is used for realizing essential building blocks, including DW generation, propagation, and pinning, in all implementations of Boolean logic, which will pave the way for scalable memory-in-logic applications.

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Giant self-biased converse magnetoelectric effect in multiferroic heterostructure with single-phase magnetostrictive materials

Cited by 20 publications

References 26 publications

Enhanced self-biased direct and converse magnetoelectric effect in Pb(In1/2Nb1/2)O3–PbTiO3/NiFe2O4 bi-layer laminate composite

Enhanced self-biased direct and converse magnetoelectric effect in Pb(In1/2Nb1/2)O3–PbTiO3/NiFe2O4 bi-layer laminate composite

Electrical manipulation of magnetic anisotropy in a Fe$_{81}$Ga$_{19}$/PMN-PZT magnetoelectric multiferroic composite

Energy Efficient All-Electric-Field-Controlled Multiferroic Magnetic Domain-Wall Logic

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