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Functionally Graded Ferroics and Magnetoelectric Interactions

$340,000FY2009MPSNSF

Oakland University, Rochester MI

Investigators

Abstract

Technical Abstract Ferroics form an important sub-group of functional materials whose physical properties are sensitive to changes in electric and magnetic fields. A multiferroic is a material that exhibits two or more of the primary ferroic properties (ferromagnetism, ferroelectricity, ferroelasticity). A composite of ferromagnetic and ferroelectric materials will allow coupling between magnetic and electric subsystems that is mediated by mechanical forces and is a magneto-electric (ME) multiferroic. Such composites provide the opportunity for studies on the physics of ME coupling and have enormous potential for novel devices. This project will expand research on magneto-electric interactions to the new frontier of graded ferroics. Recent studies on compositionally graded ferromagnets and ferroelectrics have discovered new phenomena including internal potentials, induced anisotropy, and spontaneous strains. The planned efforts will involve the synthesis of functionally graded bilayers and multilayers of ferrites and ferroelectrics and studies on the effects of grading and the nature of ME interactions. The grading will involve piezomagnetic coupling in ferrites and piezoelectric coefficient in ferroelectrics and will be accomplished by grading the chemical composition. Studies on ME interactions will be done over 1 mHz ? 110 GHz including low-frequency effects and coupling at electromechanical, ferromagnetic and magnetoacoustic resonances. Postdoctoral research associates, graduate and undergraduate students and high school interns will participate in the research. Collaboration with industry is also planned for technology transfer. Non-Technical Abstract This project is on composite materials that are capable of converting electrical energy to magnetic energy and have enormous potential for use in energy harvesting, energy storage and consumer electronics. The composite will have two components that respond individually to electric or magnetic field by producing a mechanical deformation. The project is aimed at tailoring properties of the two phases to accomplish improved mechanical response, and therefore, enhancement in the energy conversion efficiency. Changes in the chemical composition of each phase in a controlled manner are the avenue that will be explored to achieve these goals. Individual phases and composites with composition variations will be synthesized and characterized in terms of properties of importance for energy conversion. Postdoctoral research associates, graduate and undergraduate students and high school interns will participate in the research. Collaboration with industry is also planned for technology transfer.

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