Porous Fe3O4 sub-micro particles with sphere-like, cube-like and walnut-like morphologies were obtained by a two-step process, and the electromagnetic properties of the Fe3O4 particle/wax composites were investigated....Porous Fe3O4 sub-micro particles with sphere-like, cube-like and walnut-like morphologies were obtained by a two-step process, and the electromagnetic properties of the Fe3O4 particle/wax composites were investigated. The reflect loss was less than -20 dB for all of the composites in different frequency ranges. The cube-like and walnut-like Fe3O4 composites exhibit improved complex permittivity and permeability and dual-frequency and wide bandwidth absorption characteristics, which is mainly attributed to the larger shape anisotropy. Such a high absorption property indicates that these porous Fe3O4 particles with various morphologies are very promising for electromagnetic wave absorptive materials.展开更多
基金supported by the National Natural Science Foundation of China (Grant Nos. 51072038, 50772025 and 21001035)NECT, Outstanding Youth Foundation of Heilongjiang Province (Grant No. JC201008)+4 种基金the Natural Science Foundation of Heilongjiang Province, China (Grant No. F200828)the Ministry of Science and Technology of China (Grant No. 2008DFR20420)the Fundamental Research Funds for the Central Universities (Grant Nos. HEUCFT1010, HEUCF101016, HEUCF20111124 and HEUCF101016)the National Basic Research Program of China (Grant No. 2007CB310500)Harbin Key Sci-Tech Project (Grant No. 2010AA4BG004)
文摘Porous Fe3O4 sub-micro particles with sphere-like, cube-like and walnut-like morphologies were obtained by a two-step process, and the electromagnetic properties of the Fe3O4 particle/wax composites were investigated. The reflect loss was less than -20 dB for all of the composites in different frequency ranges. The cube-like and walnut-like Fe3O4 composites exhibit improved complex permittivity and permeability and dual-frequency and wide bandwidth absorption characteristics, which is mainly attributed to the larger shape anisotropy. Such a high absorption property indicates that these porous Fe3O4 particles with various morphologies are very promising for electromagnetic wave absorptive materials.
