Magnetorheological foams for multiferroic applications

•Magnetorheological foam is a silicone porous structure with magnetorheological filler.•FE porous structure can be obtained by adding of FE particles in liquid silicone.•Material based on FE structure and magnetic elastomer showed magnetoelectric effect.•The dependence of MEE on H is nonmonotonic wi...

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Veröffentlicht in:	Journal of magnetism and magnetic materials 2019-09, Vol.485, p.413-418
Hauptverfasser:	Makarova, L.A., Alekhina, Yu.A., Omelyanchik, A.S., Peddis, D., Spiridonov, V.V., Rodionova, V.V., Perov, N.S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Composite materials Deformation effects Elastomers Electric fields Ferroelectric materials Ferroelectricity Ferrofluid Ferrofluids Magnetic nanoparticles Magnetic properties Magnetism Magnetorheology Microparticles Multiferroics Porous materials Rheological properties
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container_title	Journal of magnetism and magnetic materials
container_volume	485
creator	Makarova, L.A. Alekhina, Yu.A. Omelyanchik, A.S. Peddis, D. Spiridonov, V.V. Rodionova, V.V. Perov, N.S.
description	•Magnetorheological foam is a silicone porous structure with magnetorheological filler.•FE porous structure can be obtained by adding of FE particles in liquid silicone.•Material based on FE structure and magnetic elastomer showed magnetoelectric effect.•The dependence of MEE on H is nonmonotonic with maximum value at 3.3 kOe.•The model of MEE is based on inverse magnetodeformation effect. Composite rheological materials based on ferroelectric porous structure and either magnetic elastomer or fluid filler were investigated. Ferroelectric porous structure was prepared using silicone matrix and ferroelectric PZT microparticles. Different types of liquid magnetic mixtures were placed into the porous foam like in a sponge. The influence of external electric field on the magnetic properties of such composites was detected by vibrating sample magnetometer with added voltage source. Coefficient of inverse magnetoelectric transformations of the sample with elastic filler was found to depend on magnetic field. It maximum value for the sample with iron microparticles was found to be ∼36 µG cm/V. Comparing the properties of the ferroelectric foam with ferrofluid and magnetic elastomer, we propose a qualitative model of magnetoelectric effect associated with deformation effects in components and with magnetization mechanism.
doi_str_mv	10.1016/j.jmmm.2019.04.001
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Composite rheological materials based on ferroelectric porous structure and either magnetic elastomer or fluid filler were investigated. Ferroelectric porous structure was prepared using silicone matrix and ferroelectric PZT microparticles. Different types of liquid magnetic mixtures were placed into the porous foam like in a sponge. The influence of external electric field on the magnetic properties of such composites was detected by vibrating sample magnetometer with added voltage source. Coefficient of inverse magnetoelectric transformations of the sample with elastic filler was found to depend on magnetic field. It maximum value for the sample with iron microparticles was found to be ∼36 µG cm/V. 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Composite rheological materials based on ferroelectric porous structure and either magnetic elastomer or fluid filler were investigated. Ferroelectric porous structure was prepared using silicone matrix and ferroelectric PZT microparticles. Different types of liquid magnetic mixtures were placed into the porous foam like in a sponge. The influence of external electric field on the magnetic properties of such composites was detected by vibrating sample magnetometer with added voltage source. Coefficient of inverse magnetoelectric transformations of the sample with elastic filler was found to depend on magnetic field. It maximum value for the sample with iron microparticles was found to be ∼36 µG cm/V. 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Composite rheological materials based on ferroelectric porous structure and either magnetic elastomer or fluid filler were investigated. Ferroelectric porous structure was prepared using silicone matrix and ferroelectric PZT microparticles. Different types of liquid magnetic mixtures were placed into the porous foam like in a sponge. The influence of external electric field on the magnetic properties of such composites was detected by vibrating sample magnetometer with added voltage source. Coefficient of inverse magnetoelectric transformations of the sample with elastic filler was found to depend on magnetic field. It maximum value for the sample with iron microparticles was found to be ∼36 µG cm/V. Comparing the properties of the ferroelectric foam with ferrofluid and magnetic elastomer, we propose a qualitative model of magnetoelectric effect associated with deformation effects in components and with magnetization mechanism.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.jmmm.2019.04.001</doi><tpages>6</tpages></addata></record>
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subjects	Composite materials Deformation effects Elastomers Electric fields Ferroelectric materials Ferroelectricity Ferrofluid Ferrofluids Magnetic nanoparticles Magnetic properties Magnetism Magnetorheology Microparticles Multiferroics Porous materials Rheological properties
title	Magnetorheological foams for multiferroic applications
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