Single-phase diluted magnetic systems Zn1-xFexO have been prepared by chemical route. Structural and spectroscopic (UV-Vis and Mossbauer) studies indicate the incorporation of Fe^3+ ions in the lattice sites. The U...Single-phase diluted magnetic systems Zn1-xFexO have been prepared by chemical route. Structural and spectroscopic (UV-Vis and Mossbauer) studies indicate the incorporation of Fe^3+ ions in the lattice sites. The UV-Vis results point to a systematic increase in the band gap with increasing Fe doping. The room temperature magnetization of Zni-xFexO indicates a paramagnetic behavior which is in accordance with the Mossbauer results, illustrating quadrupolar doublet. At low temperature, the zero-field-cooled (ZFC) magnetization shows a cusp and this temperature increases systematically with decreasing particle size. The weak exchange bias effect manifested by a M-H loop shift is observed for x = 0.03. This shift is accompanied by the enhancement of coercivity. The dc magnetization results suggest the coexis tence of ferromagnetic and antiferromagnetic exchange interactions for low doping of Fe, i.e., for x = 0.03.展开更多
文摘Single-phase diluted magnetic systems Zn1-xFexO have been prepared by chemical route. Structural and spectroscopic (UV-Vis and Mossbauer) studies indicate the incorporation of Fe^3+ ions in the lattice sites. The UV-Vis results point to a systematic increase in the band gap with increasing Fe doping. The room temperature magnetization of Zni-xFexO indicates a paramagnetic behavior which is in accordance with the Mossbauer results, illustrating quadrupolar doublet. At low temperature, the zero-field-cooled (ZFC) magnetization shows a cusp and this temperature increases systematically with decreasing particle size. The weak exchange bias effect manifested by a M-H loop shift is observed for x = 0.03. This shift is accompanied by the enhancement of coercivity. The dc magnetization results suggest the coexis tence of ferromagnetic and antiferromagnetic exchange interactions for low doping of Fe, i.e., for x = 0.03.