BiFeO₃ nano-materials doped with different concentrations of Cobalt oxide Bi Fe_1−xCo_xO₃ where (x = 0, 3, 5 and 10%), (BFO, BF3CO, BF5CO and BF10CO), as shown in Table 1, in powder form have been prepared by a modified sol-gel method. Bismuth (III) nitrate penta-hydrate (Aldrich, 99.5%), iron (III) nitrate non-ahydrate (Aldrich, 98%) and Cobalt (II) nitrate non hydrate were used as precursor materials. In a typical synthesis of BiFeO₃ nano-materials 0.01 mol Bi (NO₃)₃-5H₂O and 0.01 mol Fe (NO₃)₃-9H₂O were initially dissolved in the dilute nitric acid (20% HNO₃) to form a transparent solution. Ethylenediamine tetraacetic acid (EDTA) in 1:1 mol ratio with respect to the metal nitrates Bi and Fe was added to the above solution as a chelating agent. The solution was then heated at 130^◦C under constantly stirring in an oil bath until all liquid evaporated out from the solution. Crystallization of the gel was achieved by calcinating in air for 1 h at 600^◦C, in a muffle furnace type (CarboliteCWF1200).

The phases of the obtained samples are characterized by X-ray diffraction (XRD) (BRUKUR D8 ADVANCED

TARGET Cu Kα with Secondary monochromatic KV = 40, mA = 40 Germany) in a wide range of Bragg angle from 10˚ - 80˚ using Cu Ka (1.5406 Å) radiation with a step size of 0.02 at room temperature. The crystallite size (G) is determined from the Scherrer’s equation;

where K is the Scherer constant, in the present case K = (0.9), l is the wavelength and D is the full width (in radians) of the peak at half maximum (FWHM) intensity. The microstructure and surface morphology of the samples were observed by (TEM) transmission electron microscope (using JEOL JEM-1230 equipment operating at 120 kV with attached CCD camera) and (SEM) scanning electron microscope (Quanta 250 FEG (Field emission Gun)) was used to determine grain size and uniformity of the sample analysis. The phase transitions above room temperature have been investigated by DTA (SDT Q 600 V 20.9 Build 20) measurements.

(J-E) curve was measured by using kethlay and ferroelectric hysteresis loops were measured device by using ferroelectric loop tracer at a frequency of 50 Hz.

Magnetization hysteresis (M-H) measurements were carried out at room temperature using lakeshore vibrating sample magnetometer (VSM 7410) model lakeshore 7110.

The relative dielectric permittivity was calculated using the relations:

where C is the capacitance of the measured sample in Farad, d is the thickness of the sample in meters, A is the cross section area of the sample and ε_o is the permittivity of free space (8.854 × 10⁻¹² Fm⁻¹).

where, ε" is the dielectric loss and tanδ is the loss tangent.

The AC resistivity (ς') of the prepared samples has estimated from the dielectric parameters. As long as the pure charge transport mechanism is the major contributor to the loss mechanism, ς' can be calculated using the following relation:

where, w is the angular frequency and f is the frequency of the applied electric field in Hertz.

where σ is the A.C. conductivity, f is the operating frequency, d is the thickness of the dielectrics, tanδ is the dielectric loss, C is the capacitance and A is the area of the electrode.

XRD patterns of BiFeO₃ (BFO) nanoparticle in powder form calcined in air at 600˚C for 1 h is shown in Figure 1, which indicates that drying in an oil bath reduce the impurity and identifying the phase structure. Observed peaks in the XRD patterns could be identified to be rhombohedra distorted pervoskite structure of BiFeO₃ with space group R3c according to (ICDD No 86-1518). Beside these prominent peaks, some other peaks of low intensity are observed, which do not belong to pervoskite BFO, informing the Bi₂Fe₄O₉ impurity phase presence [11] .

Figure 2 shows the XRD patterns of (BFO, BF3CO, BF5CO and BF10CO) calcined at 600˚C for one hour. The same observed peaks in the XRD patterns detected in (BFO), Figure 1 appeared and could be indexed to rhombohedra distorted pervoskite structure of BiFeO₃ with space group R3c (JCPDS No 86-1518). Beside these prominent peaks, some other peaks of low intensity are observed, which do not belong to pervoskite BFO, informing the Bi₂Fe₄O₉ impurity phase presence as indicated before for (BFO). It is clear that small concentrations of cobalt (x = 0.03 and 0.05) causes stabilization to BFO rhombohedra perovskite structure with no indication of any detectable secondary phases. Since the Co²⁺ ion has similar radius as that of Fe³⁺ ion (0.65 Å for Co²⁺ and 0.645 Å for Fe³⁺; six coordination) [12] . This makes it possible for Co ions to substitute Fe ions. Figure 3 shows the expansion of the XRD patterns in the range between 2θ = 28˚ and 38˚ of BFO, (BF3CO), (BF5CO) and (BF10CO). Compared with BFO₃, no large shift toward lower 2θ side can be observed for the major peaks position of BiFe_1-xCo_xO₃ (x = 0, 0.03, 0.05, 0.1). However, the peak splitting gradually decreases by increasing Co ion concentrations in BFCO.

This result reveals that the basic rhombohedra distorted perovskite structure of BFO, (BF3CO), (BF5CO) and (BF10CO) has been affected by the substitution of Co ions. No impurity phases of Co oxides can be observed at low concentration in XRD patterns, which confirms that Co atoms have been successfully incorporated into the host lattice.

The plot of cell volume as a function of cobalt concentration is shown in Figure 4. Shrinkage in lattice parameter and unit cell volume may be expected as shown in Table 2. A systematic decrease in lattice volume, at (x = 0, 0.03 and 0.05) indicated successful substitution of cobalt at Fe site. By increasing the Co concentration up to x = 0.1 the phase purity disappeared. The appearance of the impurity at higher Co concentration could be an indication that the saturation level of forming a solid solution has been reached just before this concentration.

The average crystallite sizes of our samples calculated using Scherrer’s formula were decreased by doping with Co ions to be equal to 42 and 18 nm for BFO, and BF5CO, respectively.

Figure 5 shows the FTIR spectra of x = 0 (a), 0.03 (b), 0.05 (c) and 0.1 (d) recorded at room temperature. One of the fundamental absorptions is observed in the wavelength region between 440 and 460 cm⁻¹. This band is attributed to the bending vibration of the Fe-O bond (nearly at 444 cm⁻¹) in the FeO₆ octahedral unit However, the most important as well as complex part of the spectra is the region from 480 to 600 cm⁻¹ in the pristine BFO, which become broader by Co ions-doping. It can be seen that the extent of broadening increases by increasing dopant concentration. Another peak of Fe-O at 810 cm⁻¹ can be attributed to the formation of highly crystalline BFO phase [13] [14] .

Figures 6(a)-(c) show the transmission electron (TEM) micrographs along with their corresponding (selected

area electron diffraction, SAED) patterns of the powder samples BiFe_1−xCo_xO₃ (x = 0, 0.03, 0.05). Some degree of agglomerations has been found in the clusters, which contain many small grains. A clear and strong SAED patterns observed and confirmed that the powder samples are with good crystalline structure and have a bimodal size distribution with large particles 57 nm and smaller ones 17 nm. The particle shapes of the as synthesized samples are displayed nanostructure scale by doping the samples with x = 0.03 and 0.05 mol% of Co ions. The particle size is slightly greater than the crystallite size (C.S.) obtained by the Scherrer’s equation (XRD section) due to the presence of both microstrain and the particles agglomeration. The calculated average crystallite size obtained from TEM are about 43, 22.5 and 23.3 nm for the pure powder sample and the doped with BFO, BF3Co and BF5Co, respectively. The BiFe_1−xCo_xO₃ TEM shows good consistency with the obtained C.S. from XRD results (42, 20 and 18 nm) for the same samples. The TEM C.S. reveals a decrease in the doped samples than the pure one. The presence of sharp diffraction spots indicating the formation of well developed, highly crystalline nanoparticles. Figure 7(a) and Figure 7(b) show a small nanorod shapes for the samples doped with Co ions with x = 0.03 and 0.05 in another regions of the samples.

The FESEM images of BiFe_1−xCo_xO₃ (x = 0, 0.03, 0.05, 0.1) ceramics are displayed in Figures 8(a)-(d). The SEM micrographs reveal microstructure comprising of various size grains with well-defined boundaries, indicating polycrystalline material nature. The morphology of the samples shows relatively uniform grain size distribution; it is clear that the grains appear to stick to each other and accumulated in small amount, which may be due to presence of large oxygen vacancies. The sample micrographs are denser at higher concentrations. The grain size appears to be in nano-scale and confirms the data obtained from XRD pattern and TEM.

The phase transition and thermal stability of BFO sample above room temperature are investigated by DTA measurements as shown in Figure 9. The endothermic peak was observed at 829.15˚C during heating, indicating the BFO ferroelectric phase transformation. The obtained result is in agreement with the previously reported [2] [3] .

Figures 10(a)-(c) show the frequency dependence of the dielectric constant, dissipation factor (tanδ) and A.C.

conductivity (σ_ac) variations in the range between 1 kHz and 5 MHz for BFOC_x, where x = 0, 0.03, 0.05, and 0.1. It is observed that both ε' and “tanδ” are dependent on frequency, where it decreases at higher frequency region. But relatively at lower frequency region, dielectric constant shows a dielectric dispersion evidently. Such dispersion seems to be a common feature in ferroelectric materials concerned with ionic conductivity, which is referred as low-frequency dielectric dispersion. When the frequency increases, the relative effect of ionic conductivity becomes small and as a result, the frequency dependence of ε' becomes weak. It is known that, value of dielectric constant ε' at lower frequencies normally depends on the lattice vibrations, excitation of bound electrons, dipole orientation, and space charge polarization (atomic and electronics). At higher frequency region, the value of ε' is almost constant. This flat type characteristic at higher frequencies indicated that there is no space charge polarization contribution at this frequency range. Oxygen vacancy is one of the main sources of movable space charges in BFO [14] . There are always some oxygen vacancies in un-substituted BiFeO₃, which result in relatively small dielectric constant. Normally, the mobile oxygen vacancies can be readily activated to be free for conduction by the electric field because energy levels associated with (VO⁻²) are very close to the conduction band, However, when Co²⁺ ions was doped into BFO lattice, defect complexes between electric acceptors Co²⁺ and VO⁻² were formed [15] . The increased mobile oxygen vacancies resulted in the increase of both the dielectric constant and ac conductivity and a decrease of loss tangent at 5 mol% Co as compared with BFO nano- composite. The physical reason for the dispersion of dielectric constant can be understood on the basis of hopping of electrons between Fe²⁺-Fe³⁺ pairs of ions. The applied electric field displaces the electrons slightly from their equilibrium positions, thus producing polarization.

In case of (tanδ) it was noticed that this attenuation by increasing frequency might be attributed to the phonon dipole interaction which led to a lowering of the energy transferred to the dielectric medium. In addition, the increase of ε' and the decrease in tanδ by increasing the Co ions concentration up to 5 mol% were due to the high leakage current in the BiFeO₃ pellet. But at 0.1 mol% of Co ions the trend is completely different, this might be due to the Bi₂Fe₄O₉ impurity phase presence as shown in the XRD part in this work.

Figure 10(d) shows the leakage current density (LCD) of BiFe_1−xCo_xO₃ (x = 0, 0.03, 0.05, 0.1). The LCD of the powder at x = 0 was 10⁻⁴ A/cm² under 100 V/cm as electric field. After doping with 5 mol% Co, the LCD was increased significantly to be 0.013 A/cm² referring to the optimum condition for the electric properties.

Figure 11 shows the polarization-electric field (P-E) hysteresis loop of BiFe_1−xCo_xO₃ (x = 0.03 & 0.05). The remnant polarization (P) and the coercive electric field (EC) obtained from the P-E hysteresis loops are about 1 μC/cm² and 3 V/cm, respectively. No saturation in polarization-electric field (P-E) curve could be obtained for both ceramics at this minimum applied electric field range due to the relatively large leakage current in the samples, only low field electric hysteresis loops were obtained. The samples are highly conductive at room temperature and only partial polarization reversal takes place.

The relatively high conductivity of BiFeO₃ is known to be attributed to the variable oxidation states of Fe ions (Fe²⁺ to Fe³⁺), which require oxygen vacancies for charge compensation. Also during synthesis, the slow heating rate and long sintering time will enable the equilibrium concentration of the oxygen vacancies at high temperature (600˚C) to be reached and will result in the high oxygen vacancy concentration in the synthesized product. So the presence of Fe²⁺ ions and oxygen deficiency leads to high conductivity. No saturated polarization hysteresis loop has been observed for all samples at room temperature under such applied field due to high conductivity of the samples. It is clear that the optimum condition of the ferroelectric characteristic is at 5 mol% Co concentration. It is needed to be further study by applying the polarization using a bigger volt or kilo volt range to obtain saturation in polarization. The prepared materials have the potential of future development as powders RT multiferroic, by preparing it under annealing atmosphere to reduce oxygen vacancies, which allow us to switch polarization at higher applied voltage.

Figure 12(a) shows the room temperature magnetization hysteresis loops for BiFe_1−xCo_xO₃ (x = 0) powders calcined at 600˚C. M-H curve exhibits a nonlinearity with the remanent magnetization of 0.001 emu/g and coercive field of 125.67 Oe (as shown in Table 3), confirming the weak ferromagnetism nature at room temperature. In fact, at x = 0 the sample exhibited a G-type antiferromagnetic ordering, but has a residual magnetic moment caused by its canted spin structure (weak ferromagnetism). The weak ferromagnetic order itself can be understood as a result of noncolinear (canted) spin arrangements in two sublattices [16] . Figure 12(b) shows shifted hysteresis loops for the BFO according to Ne’el is further supported by the observation of a shift in the hysteresis loops shown in Figure 13(b), which can be ascribed to the presence of exchange coupling between the ferromagnetic surfaces and the antiferromagnetic cores. The apparently shifted coercivities, HC, are shown in the curve. The shape of our hysteresis loops, which exhibit very small remnant magnetization and a lack of saturation, reflect exchange and dipolar inter-particle interactions in addition to interfacial cross grain-boundary interactions due to the high packing volume fraction in our system. Figure 13 shows M-H curves of BiFe_1−xCo_xO₃ (x = 0.03, 0.05 and 0.1) powders calcined at 600˚C for 1 h at different concentrations of Cobalt ions, we can see that saturation magnetization (Ms) increases with the decrease in particle size and as a result of increasing the cobalt ion concentrations. It is known that magnetism in oxide nanoparticles arises from vacancies, so the increase in magnetization of BF10CO as a result of increasing in oxygen vacancies and impurities as obtained from XRD patterns can be expected to be present. The weak magnetic property of BFO nanoparticles should be attributed to the size-confinement effects of the BFO nanostructures, which correlate with: a) the increased suppression of the known spiral spin structure (period length of 62 nm) with decreasing nanoparticle size and b) uncompensated spins and strain anisotropies at the surface (Park et al. [17] ). The enhancement of the ferromagnetism of the BFCO could be attributed to the magnetic moment of Co²⁺ and the possible breakage of the space modulated spin cycloid period. It is well known that in the BFO there is an existed cycloid modulated period of magnetization of 62 nm which make BFO showing no or weak ferromagnetization [18] . Since the Co²⁺ ions have similar radius as that of Fe³⁺ ion (0.65 Å for Co²⁺ and 0.645 Å for Fe³⁺; six coordinations), a structural distortion can be expected. On the other hand, the bond angle of Fe³⁺-O-Co²⁺ is different with that of Fe³⁺-O-Fe³⁺, the magnetic moments of Fe³⁺ and Co²⁺ are different also, so the net magnetic moment is changed. The changes of both structure and net magnetic moment may change the canting of the antiferromagnetic arranged neighboring spins and break the spiral spin configuration and then enhance the magnetization. There will be a dependence of anisotropy constant K on the Co²⁺ ion concentration x, which can be evaluated by using the following relation K = HC MS/2 [19] - [23] .

The magnetic moment of Co²⁺ and Fe³⁺ ions are equal to 3 B.M, and 5 B.M, respectively, when Co²⁺ ion concentrations increased this leads to the compensation of Fe³⁺ ions in the octahedral location. That increasing of Co-concentration led to increase the total magnetization and hence an increase of MS was detected. Thus, the increase of Co-concentration led to the increase of ferrites anisotropy property, hence HC increases as shown in Table 3.