Oxygen and Cation Ordered Perovskite, Ba2Y2Mn4O11

TL;DR

This paper reports a new synthesis route for an oxygen-ordered double perovskite, Ba2Y2Mn4O11, revealing its structure and magnetic properties, and demonstrating a sharp oxygen content transition at 600°C.

Contribution

A novel three-step synthesis method for Ba2Y2Mn4O11 with detailed structural and magnetic characterization, expanding understanding of oxygen ordering in perovskites.

Findings

Successful synthesis of Ba2Y2Mn4O11 via a controlled oxygenation process.

Identification of an orthorhombic structure with oxygen ordering.

Observation of a ferromagnetic transition at approximately 133 K.

Abstract

A three-step route has been developed for the synthesis of a new oxygen-ordered double perovskite, BaYMn2O5.5 or Ba2Y2Mn4O11. (i) The A-site cation ordered perovskite, BaYMn2O5+d, is first synthesized at d ~ 0 by an oxygen-getter-controlled low-O2-pressure encapsulation technique utilizing FeO as the getter for excess oxygen. (ii) The as-synthesized, oxygen-deficient BaYMn2O5.0 phase is then readily oxygenated to the d ~ 1 level by means of 1-atm-O2 annealing at low temperatures. (iii) By annealing this fully-oxygenated BaYMn2O6.0 in flowing N2 gas at moderate temperatures the new intermediate-oxygen-content oxide, BaYMn2O5.5 or Ba2Y2Mn4O11, is finally obtained. From thermogravimetric observation it is seen that the final oxygen depletion from d ~ 1.0 to 0.5 occurs in a single sharp step about 600 C, implying that the oxygen stoichiometry of BaYMn2O5+d is not continuously tunable within 0.5 < d < 1.0. For BaYMn2O5.5 synchrotron x-ray diffraction analysis reveals an orthorhombic crystal lattice and a long-range ordering of the excess oxygen atoms in the YO0.5 layer. The magnetic behavior of BaYMn2O5.5 (with a ferromagnetic transition at ~ 133 K) is found different from those previously reported for the known phases, BaYMn2O5.0 and BaYMn2O6.0.