An Initio Study of Magnetoelectric Multiferroic Thin Films
University Of California-Santa Barbara, Santa Barbara CA
Investigators
Abstract
TECHNICAL SUMMARY: This award supports theoretical and computational research that builds on recent advances in the fields of magnetoelectric multiferroics and thin film ferroelectrics, to design and create novel magnetoelectric multiferroics and understand their behavior in thin film form. The PI seeks to help elucidate the interplay between chemistry, ordering and strain in determining the electronic and magnetic properties of thin film magnetoelectric multiferroics. There are two sub-projects: (i) The design of novel thin film multiferroics by exploiting compositional inversion symmetrybreaking to engineer ferroelectricity into otherwise non-ferroelectric magnetic materials. This strategy enables the PI to circumvent the contraindication between the conventional mechanism for ferroelectricity and the existence of magnetism. (ii) The determination of the effects of strain on the ferroelectric behavior of multiferroics. The PI aims to identify or design multiferroics in which either, strain can be exploited to enhance the polarization, or excessive strain dependence of the polarization can be avoided. The research will also test the appropriateness of the various beyond-LDA approaches for describing strongly-correlated magnetic insulators. This award also supports the extension of a senior undergraduate / beginning graduate level Access Grid-based cyber course on Magnetism and magnetic materials developed under the previous Information Technology Research award. In an associated outreach effort, the PI plans to develop a hands-on classroom kit for teachers on Materials Chemistry for 5th Grade to address topics in the California Science Standards. The cyberinfrastructure aspects of this award include: advanced computational research, cyber course development, and fundamental materials research that contributes to the foundations of future cyberinfrastructure. NON-TECHNICAL SUMMARY: This award supports theoretical and computational research on magnetoelectric multiferroics. These are materials that simultaneously display magnetism and ferroelectricity, the electrical analog of magnetism, in the same phase. The PI aims to use theory and computation to design and create novel magnetoelectric multiferroic materials and understand their behavior in thin film form. The research will help to elucidate how the interplay between chemistry, ordering and strain determines the electronic and magnetic properties of thin film magnetoelectric multiferroics. Few multiferroic materials are currently known. They have potential technological applications in information technology and the next generation of cyberinfrastructure. In addition to possessing the combined functionalities of their parent ferromagnets and ferroelectrics, coupling between the two phenomena opens new device paradigms, in which electronic behavior is controlled by a magnetic field and magnetic behavior is controlled by an electric field. A strong collaboration with synthetic materials scientists and device physicists, aims to ensure synergy between this theoretical effort, the experimental growth and characterization of new materials, and the incorporation of newly discovered materials into devices. This award also supports the extension of a senior undergraduate / beginning graduate level Access Grid-based cyber course on Magnetism and magnetic materials developed under the previous Information Technology Research award. In an associated outreach effort, the PI plans to develop a hands-on classroom kit for teachers on Materials Chemistry for 5th Grade to address topics in the California Science Standards. The cyberinfrastructure aspects of this award include: advanced computational research, cyber course development, and fundamental materials research that contributes to the foundations of future cyberinfrastructure.
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