Modeling and Physics of Multiferroic Perovskite Manganites

Abstract

A new type of multiferroicity was experimentally discovered in 2003 in a perovskite manganite TbMnO3 where its ferroelectricity is induced by cycloidally ordered Mn spins. Susequently, such spin-cycloid multiferroic phase was also discovered in RMnO3 with other rare-earth ions R=Dy, Eu1-xYx, Tb1-xGdx, etc. In this class of materials, the magnetism and ferroelectricity are inseparably coupled, and resulting strong magnetoelectric coupling enables us to control/manipulate the electricity (magnetism) by magnetic (electric) fields. Moreover, many interesting magnetoelectric phenomena due to their cross correlation have been discovered. In this article, we discuss a microscopic theoretical model for RMnO3 constructed by taking into account their precise electronic and lattice structures and overview the theoretical works based on this model which elucidated rich magnetoelectric phenomena of RMnO3. The perovskite manganites are not only the first-discovered spin-spiral multiferroic materials but also a typical class of materials that exhibits most of the magnetoelectric phenomena manifested in many other multiferroics. Therefore, the comprehensive understanding of RMnO3 directly leads to the clarification of universal physics of magnetoelectric phenomena in multiferroic materials.

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