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Partic. vol. 24 pp. 210-215 (February 2016) doi: 10.1016/j.partic.2015.08.002
Controllable hydrothermal synthesis of star-shaped Sr3Fe2(OH)12 assemblies and their thermal decomposition and magnetic properties
Heng Zhang*, Tingting Wang, Xiuping Chen, Wancheng Zhu
Highlights
Abstract
Pure phase star-shaped hydrogarnet Sr3Fe2(OH)12 assemblies were synthesized by a mild hydrothermal method (210 °C, 12 h), and the effects of the preparation conditions on the phase composition of the product were investigated. It was found that the impurity phases could be decreased or eliminated by increasing the molar ratio of Sr2+ to Fe3+, and that high temperatures favored the formation of Sr3Fe2(OH)12 and reduced the concentration of CO32--containing byproducts. The thermal decomposition of the star-shaped Sr3Fe2(OH)12 assemblies was examined, and the results showed that the dehydration process at higher temperatures is accompanied by the formation of SrFeO3–δ. Above 655 °C, a solid state reaction between the SrFeO3–δ and Sr(OH)2 or SrCO3 results in the formation of Sr4Fe3O10–δ.The magnetic properties of the as-synthesized Sr3Fe2(OH)12 and of samples calcined at different temperatures were assessed. A sample calcined at 575 °C exhibited greatly enhanced ferromagnetic properties, with a remanent magnetization of 1.28 emu/g and a coercivity of 4522.1 Oe at room temperature.
Graphical abstract
Keywords
Hydrogarnet; Hydrothermal; Star-shaped; Thermal decomposition; Magnetic property