Electrical, magnetic and microwave absorption properties of multiferroic NiFe₂O₄-BaTiO₃ nanocomposites

Abstract: Multiferroic nanocomposites of xNiFe2O4/(1-x)BaTiO3 (x = 0, 0.1, 0.2, 0.3, and 0.4) (denoted as NFO-BTO) with the particle size about of 70 nm were prepared by the high energy mechanical milling combined with the thermal annealing methods. The X-ray diffraction patterns show a presence of NiFe2O4 (NFO) and BaTiO3 (BTO) phases. The values of the characteristic parameters of nanocomposites such as the coercive field (E c), the residual polarization (P r), the remanent magnetiz… Show more

“…This feature is consistent with published reports on BTO-based materials [39][40][41]. BTO is a ferroelectric material with a narrow and curved P(E) hysteresis loop [23]. Co-doping of Ca and Zr to the A and B sites of BTO slightly improved the ferroelectric properties, as shown in figure 6(a).…”

“…The comparison of magnetic and electrical properties of BTO/NFO-based composites is presented in table 1. Considering ferroelectric property, BCTZ/NFO composites in this work had higher P max , P r , and E c values than xNiFe 2 O 4 /(1-x)BaTiO 3 prepared by the same method [23]. This could be attributed to the difference in particle shape and size.…”

“…The diffraction peaks of the NFO phase were marked by open triangle symbols, whereas solid triangle symbols were for the BCTZ phase. The x = 0 sample showed only diffraction peaks of the BCTZ phase, which were crystallised into a tetragonal structure with the Pbmm space group [23]. The peak intensity of the NFO phase was increased with respect to the increase in NFO concentration in the composites.…”

“…The peak intensity of the NFO phase was increased with respect to the increase in NFO concentration in the composites. With x = 0.1-0.4, the diffraction peaks of the NFO phase could be observed, which crystallised into a cubic spinel structure with the Fd-3m space group [23]. The lattice parameters of the x = 0 sample (only BCTZ phase) were calculated using the Bragg law equation, which showed the values of a = 4.026 Å and c = 4.063 Å.…”

“…Multiferroic properties of BCTZ/NFO nanocomposites and some BTO/NFO-based composites with different compositions and fractions of ferroelectric and ferromagnetic phases.Magnetisation obtained at the highest external applied field of 30 kOe.Considering ferromagnetic properties, the BCTZ/NFO nanocomposites of this work significantly enhanced magnetic properties by improving the M s values compared to xNiFe 2 O 4 /(1-x)BaTiO 3 composites prepared by solid-state reaction[48] and high-energy ball milling[23] methods. Not only composites of a pure phase of NFO and BTO but also BCTZ/NFO composites in this work had higher M s values compared to composites of xNiFe 2 O 4 /(1-x)Ba 0.9 Sr 0.1 Ti 0.9 Zr 0.1 O 3 prepared by the mechanochemical activation technique[26] and xCoFe 2 O 4 /(1-x)Ba 0.85 Ca 0.15 Ti 0.9 Zr 0.1 O 3 composites fabricated by the sol-gel method[49].…”

Enhanced ferroelectric and ferromagnetic properties of xNiFe₂O₄/(1–x)Ba_0.94Ca_0.06Ti_0.975Zr_0.025O₃ nanocomposites

“…This feature is consistent with published reports on BTO-based materials [39][40][41]. BTO is a ferroelectric material with a narrow and curved P(E) hysteresis loop [23]. Co-doping of Ca and Zr to the A and B sites of BTO slightly improved the ferroelectric properties, as shown in figure 6(a).…”

“…The comparison of magnetic and electrical properties of BTO/NFO-based composites is presented in table 1. Considering ferroelectric property, BCTZ/NFO composites in this work had higher P max , P r , and E c values than xNiFe 2 O 4 /(1-x)BaTiO 3 prepared by the same method [23]. This could be attributed to the difference in particle shape and size.…”

“…The diffraction peaks of the NFO phase were marked by open triangle symbols, whereas solid triangle symbols were for the BCTZ phase. The x = 0 sample showed only diffraction peaks of the BCTZ phase, which were crystallised into a tetragonal structure with the Pbmm space group [23]. The peak intensity of the NFO phase was increased with respect to the increase in NFO concentration in the composites.…”

“…The peak intensity of the NFO phase was increased with respect to the increase in NFO concentration in the composites. With x = 0.1-0.4, the diffraction peaks of the NFO phase could be observed, which crystallised into a cubic spinel structure with the Fd-3m space group [23]. The lattice parameters of the x = 0 sample (only BCTZ phase) were calculated using the Bragg law equation, which showed the values of a = 4.026 Å and c = 4.063 Å.…”

“…Multiferroic properties of BCTZ/NFO nanocomposites and some BTO/NFO-based composites with different compositions and fractions of ferroelectric and ferromagnetic phases.Magnetisation obtained at the highest external applied field of 30 kOe.Considering ferromagnetic properties, the BCTZ/NFO nanocomposites of this work significantly enhanced magnetic properties by improving the M s values compared to xNiFe 2 O 4 /(1-x)BaTiO 3 composites prepared by solid-state reaction[48] and high-energy ball milling[23] methods. Not only composites of a pure phase of NFO and BTO but also BCTZ/NFO composites in this work had higher M s values compared to composites of xNiFe 2 O 4 /(1-x)Ba 0.9 Sr 0.1 Ti 0.9 Zr 0.1 O 3 prepared by the mechanochemical activation technique[26] and xCoFe 2 O 4 /(1-x)Ba 0.85 Ca 0.15 Ti 0.9 Zr 0.1 O 3 composites fabricated by the sol-gel method[49].…”

Enhanced ferroelectric and ferromagnetic properties of xNiFe₂O₄/(1–x)Ba_0.94Ca_0.06Ti_0.975Zr_0.025O₃ nanocomposites

Insights on structural and magnetic properties of BaZr0.15Ti0.85O3- NiFe2O4 lead-free multiferroics by the solid-state reaction method

Fabrication of BaTiO3/NiFe2O4 multiferroic laminated composite systems for magnetoelectric applications