Abstract
In this chapter, we address the electric field induced magnetic resonance field shift in composites of ferrite and piezoelectric components. A phenomenological theory is proposed to treat the ME coupling at frequencies corresponding to ferromagnetic resonance in a multilayer consisting of alternate layers of piezoelectric and magnetostrictive phases. We discuss two models: a simple bimorph structure and a generalized approach in which the multilayer composite is considered as a homogeneous medium. Expressions for the electric field induced magnetic resonance field shift are obtained for both cases. Magnetic resonance field shift is directly proportional to the product of the applied electric field and the ME coupling constant. A method for the calculation of magnetoelectric coefficients from experimental data is presented.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Bichurin MI, Petrov VM (1988) Magnetic resonance in layered ferrite-ferrielectric structures. Sov Phys JETP 58:2277
Bichurin MI, Petrov VM (1994) Composite magnetoelectrics: their microwave properties. Ferroelectrics 162:33–35
Bichurin MI, Petrov VM (1995) Influence of external electric field on magnetic resonance frequency in magnetic ferroelectrics. Ferroelectrics 167:147–150
Bichurin MI, Petrov VM (2012) Magnetoelectric effects in nanocomposites. In: Bichurin MI, Viehland D (eds) Magnetoelectricity in composites, Pan Stanford Publshing, Singapore, pp 91–104
Bichurin MI, Petrov RV (2013) VM Petrov magnetoelectric effect at thickness shear mode in ferrite-piezoelectric bilayer. Appl Phys Lett 103:0929021
Bichurin MI, Viehland D (eds) (2012) Magnetoelectricity in composites. Pan Stanford Publshing, Singapore, 273 p
Bichurin MI, Venevtsev YN, Didkovskaya OS, Petrov VM, Fomich NN (1990) Magnetoelectric materials: technology features and application perspectives. In: Magnetoelectric substances, Nauka, Moscow, pp 118–132 (in Russian)
Bichurin MI, Petrov VM, Kornev IA (1997) Investigation of magnetoelectric interaction in composite. Ferroelectrics 204:289–297
Bichurin MI, Kornev IA, Petrov VM, Tatarenko AS, Kiliba YuV, Srinivasan G (2001) Theory of magnetoelectric effects at microwave frequencies in a piezoelectric/magnetostrictive multilayer composite. Phys Rev B 64:094409
Bichurin MI, Petrov VM, Petrov RV, Bukashev FI, Smirnov AY (2002a) Electrodynamic analysis of strip line on magnetoelectric substrate. Ferroelectrics 280:203–209
Bichurin MI, Petrov VM, Petrov RV, Kiliba YV, Bukashev FI, Smirnov AY (2002b) Magnetoelectric sensor of magnetic field. Ferroelectrics 280:199–202
Bichurin MI, Petrov VM, Petrov RV, Kapralov GN, Kiliba YV, Bukashev FI (2002c) Magnetoelectric microwave devices. Ferroelectrics 280:211–218
Bichurin MI, Petrov VM, Srinivasan G (2002d) Modelling of magnetoelectric effect in ferromagnetic/piezoelectric multilayer composites. Ferroelectrics 280:165
Bichurin MI, Petrov VM, Kiliba YuV, Srinivasan G (2002e) Magnetic and magnetoelectric susceptibilities of a ferroelectric/ferromagnetic composite at microwave frequencies. Phys Rev B 66:134404
Bichurin MI, Petrov VM, Galkina TA (2009) Microwave magnetoelectric effects in bilayer of ferrite and piezoelectric. Eur Phys J Appl Phys 45:30801
Bichurin MI, Petrov VM, Averkin SV, Liverts E (2010) Present status of theoretical modeling the magnetoelectric effect in magnetostrictive-piezoelectric nanostructures. Part II: Magnetic and magnetoacoustic resonance ranges. J Appl Phys 107:053905
Bichurin M, Petrov V, Zakharov A, Kovalenko D, Yang SC, Maurya D, Bedekar V, Priya S (2011) Magnetoelectric interactions in lead-based and lead-free composites. Materials 4:651–702
Bichurin M, PetrovV, Priya S, Bhalla A (2012) Multiferroic magnetoelectric composites and their applications. Adv Condens Matter Phys 2012:129794
Dong S, Zhai J, Li JF, Viehland D, Bichurin MI (2006) Magnetoelectric gyration effect in Tb1 − xDyxFe2 − y/Pb(Zr, Ti)O3laminated composites at the electromechanical resonance. Appl Phys Lett 89:243512
Li N, Liu M, Zhou Z, Sun NX, Murthy DVB, Srinivasan G, Petrov AO (2011) Electrostatic tuning of ferromagnetic resonance and magnetoelectric interactions in ferrite-piezoelectric heterostructures grown by chemical vapor deposition. Appl Phys Lett 99:192502
Lou J, Pellegrini GN, Liu M, Mathur ND, Sun NX (2012) Inequivalence of direct and converse magnetoelectric coupling at electromechanical resonance. Appl Phys. Lett. 100:102907
Nan C-W, Bichurin MI, Dong S, Viehland D, Srinivasan G (2008) Multiferroic magnetoelectric composites: historical perspectives, status, and future directions. J Appl Phys 103:031101
Petrov RV, Srinivasan G, Bichurin MI, Viehland D (2007) Three-dimensional left-handed material lens. Appl Phys Lett 91:104103
Petrov RV, Pandey R, Srinivasan G, Bichurin MI (2008a) A magnetic field controlled negative-index microwave lens. Microwave Opt Tech Lett 50:2804–2807
Petrov VM, Srinivasan G, Galkina TA (2008b) Microwave magnetoelectric effects in bilayers of single crystal ferrite and functionally graded piezoelectric. J Appl Phys 104:113910
Shastry S, Srinivasan G, Bichurin MI, Petrov VM, Tatarenko AS (2004) Microwave magnetoelectric effects in single crystal bilayers of yttrium iron garnet and lead magnesium niobate-lead titanate. Phys Rev B 70:064416
Srinivasan G (2010) Magnetoelectric composites. Annu Rev Mater Res 40:153
Srinivasan G, Tatarenko AS, Mathe V, Bichurin MI (2009) Microwave and MM-wave magnetoelectric interactions in ferrite-ferroelectric bilayers. Eur Phys J B 71:371–375
Tatarenko S, Bichurin MI (2012) Microwave magnetoelectric devices. Adv Condens Matter Phys 2012:286562
Tatarenko S, Srinivasan G, Bichurin MI (2006) Magnetoelectric microwave phase shifter. Appl Phys Lett 88:183507
Tatarenko AS, Bichurin MI, Gheevarughese V et. al (2010).Microwave magnetoelectric effects in ferrite-piezoelectric composites and dual electric and magnetic field tunable filters. J. Electroceram. 24:5
Zhai J, Li J, Viehland D, Bichurin MI (2007) Large Magnetoelectric susceptibility: the fundamental property of piezoelectric and magnetostrictive laminated composites. J Appl Phys 101:014102
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Copyright information
© 2014 Springer Science+Business Media Dordrecht
About this chapter
Cite this chapter
Bichurin, M., Petrov, V. (2014). Magnetic Resonance in Composites. In: Modeling of Magnetoelectric Effects in Composites. Springer Series in Materials Science, vol 201. Springer, Dordrecht. https://doi.org/10.1007/978-94-017-9156-4_5
Download citation
DOI: https://doi.org/10.1007/978-94-017-9156-4_5
Published:
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-017-9155-7
Online ISBN: 978-94-017-9156-4
eBook Packages: Chemistry and Materials ScienceChemistry and Material Science (R0)