The nanocrystalline,porous,magnetic α-Fe microfibers with diameter of 1-2μm and grain size of about 45 nm were...
Qingrong LIANG1,Ruijiang LIU2,Xiangqian SHEN1,Jiangying SHEN2 1 School of Material Science and Engineering,Jiangsu University,Zhenjiang,China,212013 2 School of Pharmacy,Jiangsu University,Zhenjiang,China,212013
One-dimensional and quasi-one-dimensional nanostructure materials are promising building blocks for electromagnetic devices and nanosystems.In this work,the composite Ni0.5Zn0.5Fe2O4(NZFO)/ Pb(Zr0.52Ti0.48)O3(PZT) nanofibers with average diameters about 65 nm are prepared by electrospinning from poly(vinyl pyrrolidone) (PVP) and metal salts.The precursor composite NZFO/PZT/PVP nanofibers and the subsequent calcined NZFO/PZT nanofibers are investigated by Fourier transform infrared spectroscopy (FT- IR) ,X-ray diffraction (XRD),scanning electron microscopy (SEM).The magnetic properties for nanofibers are measured by vibrating sample magnetometer(VSM).The NZFO/PZT nanofibers obtained at calcination temperature of 900 °C for 2 h consist of the ferromagnetic spinel NZFO and ferroelectric perovskite PZT phases,which are constructed from about 37 nm NZFO and 17 nm PZT grains.The saturation magnetization of these NZFO/PZT nanofibers increases with increasing calcination temperature and contents of NZFO in the composite.
Microwave absorption properties of the nanocrystalline strontium ferrite (SrFe12O19) and iron (α-Fe) microfibers for single-layer and double-layer structures are investigated in a frequency range of 2 GHz 18 GHz. For the singlelayer absorbers, the nanocrystalline SrFe12O19 microfibers show some microwave absorptions at 6 GHz 18 GHz, with a minimum reflection loss (RL) value of -11.9 dB at 14.1 GHz for a specimen thickness of 3.0 mm, while for the nanocrystalline α-Fe microfibers, their absorptions largely take place at 15 GHz-18 GHz with the RL value exceeding -10 dB, with a minimum .RL value of about -24 dB at 17.5 GHz for a specimen thickness of 0.7 mm. For the doublelayer absorber with an absorbing layer of α-Fe microfibers with a thickness of 0.7 mm and matching layer of SrFe12O19 microfibers with a thickness of 1.3 ram, the minimum RL value is about -63 dB at 16.4 GHz and the absorption band width is about 6.7 GHz ranging from 11.3 GHz to 18 GHz with the RL value exceeding -10 dB which covers the whole Ku-band (12.4 GHz 18 GHz) and 27% of X-band (8.2 GHz 12.4 GHz).
The composite nanofibers of SrTiO3/SrFel2O19 with a molar ratio of 1:1 and diameter about 120 nm were prepared by electrospinning. Effects of calcination temperature on the formation, crystallite size, morphology and magnetic property were studied by infrared spectroscopy, X-ray diffraction, scanning electron microscopy and vibrating sample magnetometer. The binary phase of strontium ferrite and titanate was formed after being calcined at 900℃ for 2 h and the composite nanofibers were fabricated from nanograins of SrTiO3 about 24 nm and SrFel2O19 around 33 nm. The crystallite sizes for the nanofibers increase with increasing calcination temperature and the addition of SrTiO3 has an obvious suppression effect on SrFel2O19 grain growth. The specific saturation magnetization and remanence tend to increase with the crystallite size. With increasing calcination temperature from 900 to 1050℃, the coercivity increases initially, achieving a maximum value of 520.2 kA.m^-1 at 950℃, and then shows a reduction tendency.
Qingrong Liang Xiangqian Shen Fuzhan Song Mingquan Liu
Nanocomposite BaFe12019/a-Fe microfibers with diameters of about 1-5 μm are prepared by the organic gel- thermal selective reduction process. The binary phase of BaFe12019 and a-Fe is formed after reduction of the precursor BaFel2019/a-Fe203 microfibers at 350 ℃ for 1 h. These nanocomposite microfibers are fabricated from a-Fe (16-22 nm in diameter) and BaFe12019 particles (36--42 nm in diameter) and basically exhibit a single-phase-like magnetization be- havior, with a high saturation magnetization and coercive force arising from the exchange--coupling interactions of soft a-Fe and hard BaFe12019. The microwave absorption characteristics in a 2-18 GHz frequency range of the nanocomposite BaFe12O19/a-Fe microfibers are mainly influenced by their mass ratio of a-Fe/BaFe12019 and specimen thickness. It is found that the nanocomposite BaFelzO19/a-Fe microfibers with a mass ratio of 1:6 and specimen thickness of 2.5 mm show an optimal reflection loss (RL) of -29.7 dB at 13.5 GHz and the bandwidth with RL exceeding -10 dB covers the whole Ku-band (12.4-18.0 GHz). This enhancement of microwave absorption can be attributed to the heterostruc- ture of soft, nano, conducting a-Fe particles embedded in hard, nano, semiconducting barium ferrite, which improves the dipolar polarization, interfacial polarization, exchange--coupling interaction, and anisotropic energy in the nanocomposite BaFe12O19/a-Fe microfibers.
