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Microwave Magneto-Electric Interactions in Multiferroics

Published online by Cambridge University Press:  26 February 2011

Gopalan Srinivasan
Affiliation:
srinivas@oakland.edu, Oakland University, Physics, Walton Blvd, Rochester, MI, 48309, United States, 248 370 34129
A.S. Tatarenko
Affiliation:
tatarenk@oakland.edu, Oakland University, Physics, Rochester, MI, 48309, United States
Y. K. Fetisov
Affiliation:
fetisov@mirea.ru, Oakland University, Physics, Rochester, MI, 48309, United States
V. Gheevarughese
Affiliation:
vagheeva@oakland.edu, Oakland University, Physics, Rochester, MI, 48309, United States
M.I. Bichurin
Affiliation:
bmi@mail.natm.ru, Novgorod State University, Institute for Electronic and Information Systems, Novgorod, N/A, Russian Federation
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Abstract

Investigations on microwave magneto-electric (ME) interactions at 1-10 GHz have been carried out on yttrium iron garnet (YIG)-lead zirconate titanate (PZT) and YIG-lead magnesium niobate lead titanate (PMN-PT) bilayers. Ferromagnetic resonance is a powerful tool for such studies. An electric field E applied to the composite produces a mechanical deformation in PZT or PMN-PT, resulting in a shift in the resonance field for YIG. Information on the nature of high frequency ME coupling has been obtained from data on resonance field shift vs E. A cavity resonator or stripline structure was used. The measured ME interactions are in the range 1-5 Oe cm/kV. The coupling strength has been found to be dependent on magnetic field orientation. The strongest interaction is measured in YIG-PZT systems. The design and characterization of ferromagnetic resonance based, electric field tunable ME resonators and filters are discussed.

Type
Research Article
Copyright
Copyright © Materials Research Society 2007

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References

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