Title :
Multiferroic and magnetoelectric materialsߞnovel developments and perspectives
Author :
Kleemann, Wolfgang ; Borisov, Pavel ; Bedanta, Subhankar ; Shvartsman, Vladimir V.
Author_Institution :
Angewandte Phys., Univ. Duisburg-Essen, Duisburg, Germany
fDate :
10/1/2010 12:00:00 AM
Abstract :
Magnetoelectric (ME) materials are of utmost interest in view of both fundamental understanding and novel desirable applications. Despite its smallness, the linear ME effect has been shown to control spintronic devices very efficiently, e.g., by using the classic ME antiferromagnet Cr2O3. Similar nano-engineering concepts exist also for type-I multiferroic single phase materials like BiFeO3 and BiMnO3. Record high ME response has been realized in stress-strain coupled multiphase magnetoelectrics like PZT/FeBSiC composites, enabling applications in sensors. In type-II multiferroics, whose ferroelectricity is due to modulated magnetic ordering, the ME coupling is of fundamental interest. Higher-order ME response characterizes disordered systems, which extend the conventional multiferroic scenario toward ME multiglass (e.g., Sr1-xMnxTiO3).
Keywords :
antiferromagnetic materials; boron compounds; chromium compounds; iron compounds; lead compounds; magnetoelectric effects; manganese compounds; multiferroics; silicon compounds; stress-strain relations; strontium compounds; Cr2O3; PZT-FeBSiC; Sr1-xMnxTiO3; composites; disordered systems; ferroelectricity; magnetoelectric materials; modulated magnetic ordering; stress-strain coupled multiphase magnetoelectrics; type-I multiferroic single phase materials; type-II multiferroics; Art; Magnetic tunneling; Materials; Perpendicular magnetic anisotropy; Superconducting magnets;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2010.1682
