Effect of Zn and Ti Co-doping on structure and electrical properties of BiFeO3 ceramics

Zhu, Jianhui; Dai, Jianhui; Xu, Jie-Wang; Li, Xiaoya

doi:10.1016/j.ceramint.2018.02.131

Cited by 34 publications

(19 citation statements)

References 29 publications

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“…The saturation magnetization increases first and then decreases with increasing the sintering time. The maximal remnant magnetization is about 0.14 emu/g when the sintering time is 2 h. This enhancement of the magnetization is larger than La and Sm doped BFO ceramics but it is consistent with the Ti doped BFO [27,28]. It is well known that, BFO is a G-type antiferromagnetic helical structure whose magnetism is derived from the atomic magnetic moment.…”

Section: Resultssupporting

confidence: 72%

“…In this paper, we report the improved multiferroic properties of La, Sm and Ti co-doped BFO ceramics by appropriate sintering schedule, where La doping at the A site can reduce the leakage current, Sm doping at the A site can enhance ferroelectric properties, and Ti dop-ing at the B site can improve magnetic properties [23][24][25][26][27][28]. The phase and morphology evolution of BFO with respect to the different sintering time as well as their influence on the physical properties such as electrical and magnetic properties of BFO have also been systematically discussed.…”

Section: Introductionmentioning

confidence: 99%

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Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Li¹,

Wang²,

Gao³

et al. 2018

PAC

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Although BiFeO 3 (BFO) has attracted great attention due to its special physical properties as a typical single phase multiferroic material, the application is limited due to the formation of impurities, defects and so forth. Herein, we report improved multiferroic properties of Bi 0.78 La 0.08 Sm 0.14 Fe 0.85 Ti 0.15 O 3 (BLSFTO) ceramics by combination of co-doping and sintering schedule. BLSFTO multiferroic ceramics were prepared by using the conventional solid state reaction method and the effect of sintering time (2, 5, 10, 20 and 30 h) on the structural, dielectric and multiferroic properties was investigated systematically. The result indicates that stable BLSFTO phase with perovskite structure was formed for all the samples. Only some impurities such as Bi 2 O 4 can be observed when the sintering time is longer than 20 h, indicating that the sintering time can induce structural changes in BLSFTO and too long sintering time can remarkably increase the secondary phases. In addition, the frequency dependent dielectric properties show that sintering time has distinct effect on the frequency stability and the relaxation process. The result demonstrates that the enhanced magnetization, improved dielectric and ferroelectric properties may be correlated with the structural transformation, impurities, oxygen vacancies and grain morphology.

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Section: Resultssupporting

confidence: 72%

Section: Introductionmentioning

confidence: 99%

Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Li¹,

Wang²,

Gao³

et al. 2018

PAC

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“…Compared to the pure BFO nanofibers, it can be observed that the two major peaks, assigned to (104) and (110) planes, have slightly shifted towards higher diffraction angle values with the increasing of Cobalt concentration. This result is differing from other element doping samples (such as Y 3+ [31], Zn 2+ and Ti 4+ [17], La 3+ [32] ), which two major peaks are moving towards to the higher angle side and having merge trends with the doping element increasing [33]. It can be used a variation of Goldschmidt tolerance factor to explain as follow [17]: and + r Co 3 assigned to the radius of the Bi 3+ , O 2− , Fe 3+ and Co 3+ ions, respectively.…”

Section: Resultscontrasting

confidence: 65%

“…The strong and sharp diffraction peaks indicated good crystallinity of the samples in the patterns of the nanofibers. A small quantity of the impurity phase that identified as Bi 2 Fe 4 O 9 [15] and Bi 25 FeO 40 [29] were also detected, which could be the metastable phase come from the BFO-based materials synthesis process [17,30]. The views of the XRD patterns (2θ from 31.5°to 33.5°) was enlarged in the figure 4 (bottom).…”

Section: Resultsmentioning

confidence: 96%

“…Xie et al [15] prepared pure BFO nanofibers by the sol-gel electrospinning and studied the ferroelectric and ferromagnetic properties. On the other hand, Chemical substitution of BFO at Bi and Fe sites is also found to cause changes to the lattice and modulated the spin structure of BFO, thereby enhancing magnetic properties [17,18]. There has been a continuous effort to enhance the magnetoelectric properties of BFO by doping transition metal ions (Co, Mn, Zn, etc) at Fe sites.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced magnetic properties of cobalt-doped bismuth ferrite nanofibers

You

Zhang

2020

Mater. Res. Express

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This study demonstrates the effect of Cobalt substitution on the structure, ferroelectric, and magnetic properties of BiFeO 3 (BFO) nanofibers. The BiFe 1−x Co x O 3 (x = 0, 0.05, 0.1) nanofibers were successfully synthesized by a sol-gel based electrospinning method followed by thermal treatment. The BiFe 1−x Co x O 3 nanofibers prepared under optimized conditions are a polycrystalline fiber that presents a rhombohedral distorted perovskite structure with a little amount impurity phase. Room temperature polarization and magnetization results indicated the multiferroic behavior of the nanofibers. Especially, the remnant magnetization is increased from 0.18 emu g −1 to 1.72 emu g −1 on increasing amount of Co substitution. The improvement of magnetism can be attributed to the Cobalt doping and size-effect.

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First‐principles calculation of temperature‐dependent electronic transitions mechanism in V or Nb substituted BiFeO₃

Bian

Dong

et al. 2019

Int J of Quantum Chemistry

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Here, we present a simulation study of temperature‐dependent electronic transitions in BiVO3 (BVO) and BiNbO3 (BNO) using density functional theory (DFT) together with generalized gradient approximation (GGA) and two‐dimensional correlation analysis (2D‐CA). The results indicate that heat accumulation can accelerate the degeneracy of V‐3d orbital in BVO and the splitting of Nb‐4d orbital in BNO at 750 K. We found changes in the type of d–p hybrid orbital as follows, for BVO: V‐dx2+y2 + dZ2‐O‐2pz → V‐dx2+y2‐O‐2pz; and for BNO: Nb‐dx2+y2‐O‐2pz → Nb‐dx2+y2 + dZ2‐O‐2pz. Furthermore, we found changes in the type of hybrid orbital leading to the following electron–electron interactions, for BVO: t2g (V‐dZ2‐O‐2pz) + eg (V‐dx2+y2‐O‐2pz) → t2g (V‐dx2+y2‐O‐2pz); and for BNO: t2g + eg (Nb‐dx2+y2 + dZ2‐O‐2pz) → t2g (Nb‐dx2+y2‐O‐2pz) + eg (Nb‐dz2‐O‐2pz). The electronic transitions are determined by a charge‐transfer from the occupied O‐2p4 orbitals to the unoccupied V‐3d3 (or Nb‐4d3) and Bi‐6p3 orbitals. Due to the temperature‐dependent electronic structure closely related to these electronic transitions, this study provides a new perspective for the design and improvement of BFO‐based temperature‐sensitive devices.

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Effect of Zn and Ti Co-doping on structure and electrical properties of BiFeO3 ceramics

Cited by 34 publications

References 29 publications

Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Enhanced magnetic properties of cobalt-doped bismuth ferrite nanofibers

First‐principles calculation of temperature‐dependent electronic transitions mechanism in V or Nb substituted BiFeO₃

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Effect of Zn and Ti Co-doping on structure and electrical properties of BiFeO3 ceramics

Cited by 34 publications

References 29 publications

Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Dielectric, ferroelectric and magnetic properties of Bi0.78La0.08Sm0.14Fe0.85Ti0.15O3 ceramics prepared at different sintering conditions

Enhanced magnetic properties of cobalt-doped bismuth ferrite nanofibers

First‐principles calculation of temperature‐dependent electronic transitions mechanism in V or Nb substituted BiFeO3

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First‐principles calculation of temperature‐dependent electronic transitions mechanism in V or Nb substituted BiFeO₃