Magnetic, Dielectric and Complex Impedance Properties of xBa0.95Sr0.05TiO3-(1 - x)BiFe0.9Gd0.1O3Multiferroic Ceramics

doi:10.1007/s40195-016-0408-z

Abstract

Abstract:

xBa_0.95Sr_0.05TiO₃-(1 - x)BiFe_0.9Gd_0.1O₃ [xBST-(1 - x)BFGO] (x = 0.00, 0.10, 0.20 and 0.25) multiferroic ceramics were prepared by the standard solid-state reaction technique. Structural characterization was performed by X-ray diffraction. All the samples showed rhombohedral distorted perovskite structure. Surface morphology of the ceramics was studied by the field emission scanning electron microscope (FESEM). From the FESEM observation, the grain size was observed to be decreased with increasing BST content. Enhanced magnetic properties were observed in BFGO with the increase in BST content because of large lattice distortion. The complex initial permeability increased with the increasing of BST content. The study of dielectric properties showed that the dielectric constant increased, whereas dielectric loss decreased with increasing of BST content due to the reduction of oxygen vacancies. An analysis of the electric impedance and modulus with frequency was performed at different temperatures. Non-Debye-type relaxation processes occur in the compound which was confirmed from the nature of the Cole-Cole plot. The DC conductivity was found to increase with the rise in temperature which indicates the semiconducting behavior of the compound with characteristics of the negative temperature coefficient of resistance. The activation energy, responsible for the relaxation determined from the modulus spectra (0.246 eV), was found to be almost same as the value obtained from the impedance study (0.240 eV), indicating that charge carriers overcome the same energy barrier during relaxation. The frequency response of imaginary parts of electric impedance and modulus suggested that the relaxation in xBST-(1 - x)BFGO ceramics follows the same mechanism at various temperatures.

Key words: Magnetic properties, Dielectric properties, Impedance spectroscopy, Activation energy

M. J. Miah, A. K. M. Akther Hossain. Magnetic, Dielectric and Complex Impedance Properties of xBa_0.95Sr_0.05TiO₃-(1 - x)BiFe_0.9Gd_0.1O₃Multiferroic Ceramics[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(6): 505-517.

Figures/Tables 15

Fig. 1 XRD patterns of BFO sintered at 900 °C a, various xBST-(1 - x)BFGO ceramics sintered at 950 °C b and enlarged view of (104) and (110) peaks c

Table 1 Lattice parameters, unit cell volume (V), bulk density (ρB), theoretical density (ρth), tolerance factor (t), porosity (P) and average grain size (D)

x	a (Å)	c (Å)	V (Å³)	ρ_B (g/cm³)	ρ_th (g/cm³)	t	P (%)	D (μm)
0.00	5.5457	13.7038	367	7.60	8.83	0.847	13.9	2.17
0.10	5.5790	13.6028	368	7.38	8.54	0.855	13.5	2.60
0.20	5.5859	13.5698	368	7.10	8.28	0.864	13.0	2.47
0.25	5.6001	13.7960	374	7.06	8.03	0.868	12.0	2.42

Fig. 2 Variation of ρth and ρBa, and variation of V and <rA>b with BST content of various xBST-(1 - x)BFGO ceramics sintered at 950 °C for 1 h

Fig. 3 FESEM micrographs of various xBST-(1 - x)BFGO ceramics sintered at 950 °C for 1 h: ax = 0.00; bx = 0.10; cx = 0.20; dx = 0.25

Fig. 4 M-H hysteresis loops of various xBST-(1 - x)BFGO ceramics sintered at 950 °C for 1 h: ax = 0.00; bx = 0.10; cx = 0.20; dx = 0.25

Table 2 Remnant magnetization (Mr), coercivity (Hc) and magnetic anisotropy (K) of xBST-(1 - x)BFGO ceramics at room temperature

x	M_r (emu/g)	H_c (kOe)	K (kOe emu/g)
0.00	0.014	0.791	0.160
0.10	0.011	1.106	0.175
0.20	0.012	0.012	0.003
0.25	0.080	0.005	0.002

Fig. 5 Variation of with frequency a, and Hc with BST content b and tanδ with frequency c of various xBST-(1 - x)BFGO ceramics sintered at 950 °C for 1 h

Fig. 6 Variation of ε' a and tanδb with frequency, and dependence of ε' c and tanδd on BST content of various xBST-(1 - x)BFGO ceramics sintered at 950 °C for 1 h

Fig. 7 Variation of ε' a and tanδb with temperature of xBST-(1 - x)BFGO ceramics at 1 kHz frequency sintered at 950 °C for 1 h

Fig. 8 Variation of Z′with frequency at room temperature for various xBST-(1 - x)BFGO ceramics a, and at different temperatures for 0.25BST-0.75BFGO ceramics b

Fig. 9 Variation of Z' ' with frequency a, and Arrhenius plot of frb for 0.25BST-0.75BFGO composition at different temperatures

Table 3 Values for grain resistance (Rg), grain boundary resistance (Rgb), relaxation frequency (fr), grain capacitance (Cg) and grain boundary capacitance (Cgb) of 0.25BST-0.75BFGO

Temperature (°C)	R_g (kΩ)	R_gb (kΩ)	f_r (kHz)	C_g (nF)	C_gb (nF)
50	1060	-	1.09	0.14	-
100	1250	-	1.09	0.12	-
150	55	50	6.63	0.44	0.48
200	25	15	17.00	0.37	0.62
225	9.50	4.00	40.27	0.42	0.98
250	3.80	2.20	88.22	0.48	0.82
275	1.90	0.90	178.70	0.47	0.99
300	1.05	0.48	309.41	0.49	1.07

Fig. 10 a Cole-Cole plots of Z′and Z′′at room temperature for different compositions of xBST-(1 - x)BFGO ceramics; b-i Cole-Cole plots for 0.25BST-0.75BFGO composition at different temperatures; j Arrhenius plots of grain and grain boundary conductivity for 0.25BST-0.75BFGO composition

Fig. 11 Variation of M′a and M'' b with frequency at various temperatures, Arrhenius plot of fmaxc, and M′versus M′′ curves at different temperatures d for 0.25BST-0.75BFGO composition sintered at 950 °C for 1 h

Fig. 12 Frequency responses of Z′′and M′′at 250 °C a and 300 °C b for 0.25BST-0.75BFGO composition sintered at 950 °C for 1 h

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Magnetic, Dielectric and Complex Impedance Properties of xBa_0.95Sr_0.05TiO₃-(1 - x)BiFe_0.9Gd_0.1O₃Multiferroic Ceramics

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