Enhanced ferroelectric and ferromagnetic properties of xNiFe2O4/(1–x)Ba0.94Ca0.06Ti0.975Zr0.025O3 nanocomposites

IF 1.7 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Dinh Chi Linh, D. S. Lam, Nguyen Thi Viet Chinh, D. D. Dung, Ngo Tran, T. D. Thanh
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引用次数: 1

Abstract

Bi-phase multiferroic composites of NiFe2O4/Ba0.94Ca0.06Ti0.975Zr0.025O3 (BCTZ/NFO) were successfully fabricated by high-energy ball milling combined with heat treatment. X-ray diffraction patterns and Raman spectra confirmed the successful coexistence of BCTZ and NFO phases in the final composites, which had an average particle size of 50 nm. However, the number of large particles increased with the increased NFO concentration in the composites. Optical properties of the composites were also modified by the NFO content, where the absorption band tended to the visible region and band-gap energies (E g) decreased with the increase of NFO. Ferromagnetic and ferroelectric properties of the BCTZ/NFO composites were also tuned by NFO additive content. Both saturation magnetisation (M s) and remnant magnetisation (M r) increased with the increase of NFO content, where the maximum values of M s = 22.52 emu g−1 and M r = 1.48 emu g−1 for composites with 40% NFO concentration, while coercivity (H c) was maintained at about 60 Oe. Maximum polarisation (P max), remnant polarisation (P r), and coercive field (E c) values all increased with NFO concentration, with 10% NFO providing the highest P max (= 0.249 μC cm−2) and P r (= 0.116 μC cm−2) values, and 30% NFO providing the highest E c (= 1.720 kV cm−1) value with a maximum applied voltage of 1 kV. Therefore, the multiferroic properties of BCTZ/NFO composites could be enhanced with an appropriate concentration of NFO, which led to a wide range of practical applications in the advanced electronic device field.
xNiFe2O4/(1-x)Ba0.94Ca0.06Ti0.975Zr0.025O3纳米复合材料的铁电和铁磁性能增强
采用高能球磨结合热处理法制备了NiFe2O4/Ba0.94Ca0.06Ti0.975Zr0.025O3 (BCTZ/NFO)双相多铁复合材料。x射线衍射图和拉曼光谱证实了复合材料中BCTZ和NFO相的成功共存,复合材料的平均粒径为50 nm。然而,随着复合材料中NFO浓度的增加,大颗粒的数量增加。复合材料的光学性质也受到NFO含量的影响,其吸收带倾向于可见光区,带隙能(E g)随NFO含量的增加而降低。BCTZ/NFO复合材料的铁磁性和铁电性能也随NFO添加剂含量的变化而变化。饱和磁化强度(M s)和剩余磁化强度(M r)均随NFO含量的增加而增加,当NFO浓度为40%时,复合材料的M s最大值为22.52 emu g−1,M r最大值为1.48 emu g−1,矫顽力(H c)保持在60 Oe左右。最大极化(P max)、剩余极化(P r)和矫顽力场(E c)值均随NFO浓度的增加而增加,其中10%的NFO提供了最高的P max (= 0.249 μC cm−2)和P r (= 0.116 μC cm−2)值,30%的NFO提供了最高的E c (= 1.720 kV cm−1)值,最大施加电压为1 kV。因此,适当浓度的NFO可以增强BCTZ/NFO复合材料的多铁性,在先进电子器件领域具有广泛的实际应用前景。
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来源期刊
Advances in Natural Sciences: Nanoscience and Nanotechnology
Advances in Natural Sciences: Nanoscience and Nanotechnology NANOSCIENCE & NANOTECHNOLOGYMATERIALS SCIE-MATERIALS SCIENCE, MULTIDISCIPLINARY
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