Multiferroics with both ferroelectric and magnetic polarizations are rare due to the conflicting structural and electronic requirements of magnetism and ferroelectricity. Besides the fundamental interest in such materials, multiferroics have a tremendous application potential e.g. as sensors, actuators, and memory materials. However, up to now an applied multiferroic material, not to mention one with above room-temperature functionality, remains elusive. In this proposal we suggest a novel approach to obtain an above room-temperature multiferroic by using improper ferroelectricity and charge transfer in a ferrimagnetic double perovskite system. Perovskites ABO3 (A is a rare-earth (R) or alkaline-earth element and B is a transition metal) are known for A-site driven ferroelectricity and B-site driven magnetism as in the case of the up to now most famous multiferroic BiFeO3. Its low magnetization due to canted antiferromagnetic order along with the phase-instability of Bi-containing compounds in general keeps this compound away from practicability. Double perovskite (A2BB′O6) systems with two different transition metal cations at the B-site show a wide variety of physical properties including above room-temperature ferrimagnetism. So-called hybrid improper ferroelectricity describes a state where a suited distortion pattern in a ferromagnetic material creates a ferroelectric polarization. By engineering two nonpolar ferro- or ferrimagnetic materials within a superlattice, improper ferroelectricity can be evoked, making available a novel type of multiferroic material.In the first part of this project, we propose to investigate bulk and thin films of the newly discovered double perovskite system R2FeReO6 with a well above room-temperature ferrimagnetic ordering temperature, TC, of about 730 K and a large saturation magnetization, MS, of 1.7 µB/f.u. at room temperature for R = La. Subsequently, we will fabricate and investigate La2FeReO6/R2FeReO6 thin film superlattices, synthesized by stacking in a layer-by-layer growth mode, alternately La2FeReO6 and R2FeReO6 layers, where R is a rare-earth element other than La. The resulting A-site layering with La and R will produce antipolar motions of the La and R atoms in the perovskite lattice which will induce, in turn, sizable ferroelectric polarization. The cationic ordering in both the A-site and B-site are necessary for activating ferroelectricity and ferrimagnetism in this hybrid compound. The expected charge transfer from the Re site towards the Fe site will induce a significant charge difference at the two different B-sites promoting a high degree of B-site ordering. We will use state-of-the-art pulsed laser deposition to artificially tailor A- and B-site ordered LaRFeReO6 double perovskites as above room-temperature multiferroics. Substrate induced epitaxial strain and chemical strain due to various R ionic radii are additional degrees of freedom to be implemented to tailor the ferroic orders.

DFG Programme Research Grants

International Connection France

Cooperation Partners Professor Dr. Oliver Clemens; Professorin Dr. Ulrike Ingrid Kramm; Professor Leopoldo Molina-Luna; Dr. Andrei Rogalev; Professor Dr. Hongbin Zhang, Ph.D.