Cr离子掺杂对NiZn铁氧体结构、电学及磁学性能的影响-有色金属在线

简介概要

Cr离子掺杂对NiZn铁氧体结构、电学及磁学性能的影响

来源期刊：中国有色金属学报(英文版)2020年第7期

论文作者：罗广圣洪宇昊周卫平程振之马驰骋吴仲楷黄欢欢

文章页码：1895 - 1903

关键词：NiZn铁氧体；Cr离子掺杂；电阻率；介电性能；饱和磁化强度

Key words：NiZn ferrite; chromium doping; electrical resistivity; dielectric properties; saturation magnetization

摘要：通过常规的固相烧结法成功制备Ni_0.5Zn_0.5Fe_2-xCr_xO₄(0≤x≤0.5)铁氧体，并研究Cr离子掺杂对铁氧体结构、电学及磁学性能的影响。粉末X射线衍射结果表明，所有制备的样品没有杂相，均生成结晶良好的纯尖晶石结构。随着Cr离子掺杂量增加，样品的晶格常数和微晶尺寸逐渐减少。磁性测量结果表明，饱和磁化强度随Cr离子掺杂而大幅度减少，从未掺杂时的73.5 A·m²/kg减少到掺杂比分为0.5时的46.3 A·m²/kg。室温电阻率随着Cr离子的掺杂增加至少4个数量级，在掺杂比分为0.5的样品中达到1.1×10⁸ Ω·cm。所有尖晶石样品的介电常数随着频率的增加单调减小，表现出正常的介电色散行为。介电常数随Cr离子掺杂量的变化趋势与电阻率随Cr离子掺杂量的变化趋势相反，掺杂导致Fe²⁺/Fe³⁺电偶极子数量减少，表明铁氧体中极化机制和导电机制存在着内在的关联。

Abstract: Ni_0.5Zn_0.5Fe_2-xCr_xO₄ (0≤x≤0.5) ferrites were successfully prepared by conventional solid state reaction method to investigate the effect of chromium substitution on the structural, electrical and magnetic properties. X-ray powder diffraction results demonstrate that all the prepared samples are well crystallized single-phase spinel structures without secondary phase. As chromium concentration increases, the lattice parameter and crystallite size gradually decrease. The magnetic measurement indicates that saturation magnetization is substantially suppressed by Cr³⁺ doping, changing from 73.5 A·m²/kg at x=0 to 46.3 A·m²/kg at x=0.5. While the room-temperature electrical resistivity is more than four orders of magnitude enhanced by Cr³⁺ substitution, reaching up to 1.1×10⁸ Ω·cm at x=0.5. The dielectric constant monotonously decreases with rising frequency for these ferrites, showing a normal dielectric dispersion behavior. The compositional dependence of dielectric constant is inverse with that of electrical resistivity, which originates from the reduced Fe²⁺/Fe³⁺ electric dipole number by doping, indicating inherent correlation between polarization and conduction mechanism in ferrite.

Trans. Nonferrous Met. Soc. China 30(2020) 1895-1903

Effect of chromium substitution on structural, electrical and magnetic properties of NiZn ferrites

Guang-sheng LUO^1,2, Yu-hao HONG¹, Wei-ping ZHOU^1,2, Zhen-zhi CHENG^1,2, Chi-cheng MA¹, Zhong-kai WU¹, Huan-huan HUANG¹

1. School of Materials Science and Engineering, Nanchang University, Nanchang 330031, China;

2. National Laboratory of Solid State Microstructures, School of Physics, Nanjing University, Nanjing 210093, China

Received 15 August 2019; accepted 28 May 2020

Key words: NiZn ferrite; chromium doping; electrical resistivity; dielectric properties; saturation magnetization

1 Introduction

Acquiring high performance soft magnetic materials is of demanding needs for the electrified world due to their widespread application in power electronics, electrical machines, microwave devices, transformer core, multilayer inductor, automatics, and computer facilities, etc [1-3]. Spinel ferrite is one of the important soft magnetic materials that are suitable for magnetic and electronic device applications, which have attracted substantial attention for decades [4-8]. In addition to their excellent magnetic characteristics, high electrical resistivity, low eddy current and reduced dielectric loss in spinel ferrites further widen their application to microwave frequencies [9]. The crystal structure of spinel ferrite is commonly face-centered cubic structure with space group Fd3m, which is typically expressed in the molecular formula of AB₂O₄. In this structure, A and B represent four-fold tetrahedral lattice sites (A) and six-fold octahedral lattice sites (B) in the cubic close-packed framework composed by oxygen ions [4]. According to the distribution of cations on the crystallographic site, the spinels can be categorized as normal, inverse and mixed spinel. Among the spinel family, the mixed NiZn ferrites have been intensively scrutinized for their outstanding and versatile properties, including high electrical resistivity, high magnetic susceptibility, low dielectric loss, high quality factor and high chemical stability. Further improving the application frequency and reducing the energy dissipation are key issues for high performance NiZn ferrites. Many efforts have been addressed towards enhancing the electrical resistivity, modification of dielectric and magnetic properties of mixed NiZn ferrites. Substitution is an effective avenue to modify morphological, electrical and magnetic properties, which has been widely adopted by many researchers [9-13]. Chromium ion belongs to 3d traditional metal group with similar radius with ferric ions, and can be readily substituted in the spinel lattice to adjust its physical properties. A few groups have investigated the effect of paramagnetic chromium ions substitution on the magnetic and electrical properties of NiZn ferrites. For example, KUMAIR et al [14] reported that the dielectric constant, dielectric loss and AC conductivity decrease with increasing Cr³⁺ substitution in ZnFe₂O₄. BIRAJDAR et al [15] found that the saturation magnetization for Ni_0.7Zn_0.3Fe₂O₄ is suppressed by chromium doping. GABAL et al [16] observed that the Curie temperature of Ni_0.8Zn_0.2Fe₂O₄decreases by Cr substitution. Above all, Ni_0.5Zn_0.5Fe₂O₄ exhibits the largest saturation magnetization in the NiZn ferrite series [17,18], whereas the effect of Cr³⁺ ion substitution on its properties has not been systematically reported in the literature. Therefore, it is highly needed to further investigate the Cr substituted NiZn ferrite to clarify substitution mechanism and furnish assorted properties.

In this work, we have comprehensively investigated the role of chromium substitution on the structural, morphological, electrical and magnetic properties of Ni_0.5Zn_0.5Fe₂O₄ ferrite. It is found that the electrical resistivity is effectively enhanced as much as more than four orders of magnitude by chromium doping. The underlying mechanism of chromium substitution effect on the physical properties of NiZn ferrite is substantially discussed.

2 Experimental

Ni_0.5Zn_0.5Fe_2-xCr_xO₄ (x=0, 0.1, 0.2, 0.3, 0.4 and 0.5) polycrystalline samples were synthesized by traditional ceramics method. High purity raw materials of NiO (99%), ZnO (99%), Fe₂O₃ (99%) and Cr₂O₃ (99%) were weighed according to the stoichiometric ratio. Firstly, these raw powders were completely mixed and milled in alcohol by agate balls for 4 h in a planetary ball mill, and then dried and calcined at 1100 °C for 3 h. A second ball-milling was performed following an intermediate manual grinding in an agate mortar for these pre-sintered powders. Subsequently, these powders were pressed into pellets under uniaxial dry pressing at 15 MPa for 5 min, and then sintered at 1400 °C for 4 h with a heating rate of 5 °C/min. The as-prepared pellets were polished into plates with a thickness of 0.8 mm and coated with silver electrode on both surfaces.

The phase purity was characterized by X-ray powder diffraction (BRUKER, D8 Focus) equipped with Cu K_α₁ radiation (λ=1.54056 ) at room temperature. The morphology and element mapping were carried out by scanning electron microscope (SEM) and energy dispersive spectrometer (EDS) (Hitachi, S-3400N II). The dielectric constant and tangent loss were measured by a precise impendence analyzer (Agilent 4284A LCR meter) at room temperature. The current-voltage curves were measured by two-probe method at room temperature. The magnetic properties were measured by vibrating sample magnetometer (VSM, Lakeshore-7300) at room temperature.

3 Results and discussion

3.1 X-ray diffraction

Figure 1(a) shows the XRD patterns of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ceramics collected at room temperature. All of the Bragg peaks can be well indexed in a cubic spinel structure with space group of Fd3m without secondary phase, indicating that Cr³⁺ ions were incorporated into the spinel lattice. To clearly demonstrate the effect of Cr³⁺ substitution on the structure, magnified XRD patterns of the strongest (311) peak are shown in Fig. 1(b). Obviously, the peak position gradually shifts to higher angle with increasing Cr³⁺ concentration, indicating that the spinel structure gradually shrinks with substitution. To quantitatively analyze the structural evolution by substitution, the lattice parameters are calculated from the XRD patterns by the following equation:

Fig. 1 XRD patterns of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites measured at room temperature (a) and magnified (311) peak of these XRD patterns (b)

(1)

where (h k l) are diffraction indices, θ represents the diffraction angle of the (h k l) peak, and λ is the wavelength of X-ray.

As shown in Fig. 2, the lattice parameters of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites monotonously decrease from 8.390 for parent compound to 8.361 for x=0.5 with increasing Cr³⁺ concentration. This behavior has a direct relationship with the size of the substituted ions. As reported previously, the ionic radius of Cr³⁺ (0.615 ) is smaller compared with that of Fe³⁺ (0.645 ) [19]. According to the Vegard’s law, when a portion of Fe³⁺ ions are substituted by Cr³⁺ions, the size of the unit cell shrinks, leading to decreased lattice constant. Similar phenomenon was also observed in other Cr-substituted ferrites [20]. The average crystallite size is calculated using the Scherrer’s equation: D=0.89λ/βcosθ, where λ is the wavelength of X-ray, β is the full width at the half-maximum in radians, and θ is the angle of the most intense (311) diffraction peak. The crystallite size substantially decreases from 62 to 51 nm with increasing Cr³⁺ concentration, as shown in Fig. 2.

Fig. 2 Lattice constant and crystallite size of NiZn ferrites as function of chromium substitution concentration

3.2 SEM

Microstructure and morphology of the ferrites could provide valuable information for understanding the doping effect on the physical and chemical properties of ferrite. The cross-section SEM measurements were conducted to investigate the effect of chromium doping on the particle size and morphology of NiZn ferrite, as shown in Fig. 3. All the samples are densely sintered and the Cr³⁺ doping has an impact on the structural morphology and particle size of NiZn ferrites. More specifically, rounded grains with the average size of 3.9 μm are prevalent for undoped samples. While the average particle size decreases to 2.9 μm at x=0.1. However, the grains grow rapidly and merge together by reducing grain boundaries at x=0.2 and 0.3. Further increasing the doping concentration leads to discrete grains with rounded shape, as shown at x=0.4 and 0.5. The average grain size increases from 2.1 μm at x=0.4 to 4.5 μm at x=0.5. In Fig. 4, the element mapping of sample measured by EDS at x=0.4 shows that the elements of Ni, Zn, Fe, Cr, O are all evenly distributed in the sample without obvious element aggregation.

Fig. 3 SEM images of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites

Fig. 4 Element mapping of Ni_0.5Zn_0.5Fe_1.6Cr_0.4O₄ sample

3.3 Magnetic properties

Fig. 5 Magnetic hysteresis loops of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites measured at room temperature (The inset shows the saturation magnetization (M_s) of NiZn ferrites as a function of Cr substitution level)

The magnetic hysteresis loops of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites measured at room temperature are shown in Fig. 5. All the samples exhibit typical S-shaped magnetic loops with a tiny coercive field. It can be clearly noted that the shape of M-H loops varies with Cr³⁺ substitution, which is the most obvious in the saturated region. The saturation magnetization, coercive field and remanence of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites are extracted from M-H loops, which are presented in Table 1. The saturation magnetization is plotted as a function of Cr³⁺-doping level, as shown in the inset of Fig. 5. For the undoped compound (x=0), the saturation magnetization is 73.5 A·m²/kg, which is akin with the results (70.13-84 A·m²/kg) reported by our group [21, 22] and other groups [23,24]. It can be seen that the saturation magnetization is approximately linearly suppressed by Cr³⁺ doping and reaches up to 46.3 A·m²/kg at x=0.5. The effect of Cr³⁺ substitution on the magnetic properties of NiZn ferrites can be explained by the collinear ferrimagnetic structure of spinel. As mentioned earlier, there are two different lattice sites, i.e. four-fold tetrahedral lattice sites (A) and six-fold octahedral lattice sites (B), which can be occupied by cations in spinel structure. Each ion at the A site has 12 B-site ions as the nearest neighbors. The strength of magnetic exchange interactions between magnetic atoms on A sites and B sites are dominant over than that of A-A and B-B interactions within each sublattice. Antiparallel arrangement between A- and B-site spins is formed due to the large negative A-B interaction originating from super- exchange interaction among magnetic ions via oxygen [5]. Therefore, the net magnetization of spinel ferrite can be expressed as the subtraction between the magnetization of B site sublattice (M_B) and the that of A site sublattice (M_A), i.e. M=M_B-M_A. The occupation preference of metal ions in spinel ferrite has an impact on its magnetic properties. Zn²⁺ ions have a strong tendency to occupy the A site [25], while Ni²⁺ and Cr³⁺ ions are more likely to occupy octahedral B site because of favorable crystal-field effects [19], whereas Fe³⁺ ions can distribute both on A and B sites. Therefore, the doped-Cr³⁺ ions would occupy the B site by replacement of Fe³⁺ ions. The magnetic moment of Cr³⁺ (3 Bohr magnetos) is smaller than that of Fe³⁺ (5 Bohr magnetos). The substitution of high magnetic moment Fe³⁺ ions by low magnetic moment Cr³⁺ ions on octahedral site could lead to a decrease of the magnetic moment of B sublattice. As a result, the net magnetic moment of NiZn ferrite (M=M_B-M_A) decreases with the addition chromium concentration. Interestingly, as shown in Table 1, the coercive field and remanence show trivial variation with chromium substitution and all exhibit miniscule values, indicating the excellent soft magnetic characteristic of these ferrites.

Table 1 Saturation magnetization, coercive field and remanence of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites

3.4 Resistivity

The electrical properties of ferrites are very important for their applications at high frequency. In order to investigate the role of chromium doping on electrical properties of NiZn ferrite, the current density as a function of applied field (J-V) of these samples were measured by the two-probe method at room temperature, as presented in Fig. 6(a). The almost linear dependence of current density on applied field in the double logarithmic curve implies the ohmic behavior of these samples. The electrical resistivity (ρ) is calculated by

(2)

where R is the measured resistance, S is the cross-sectional area of the samples, and L is the sample thickness.

As demonstrated in Fig. 6(b), it is observed that electrical resistivity is substantially enhanced by doping chromium ions in NiZn ferrite, from 5.3×10³ Ω·cm at x=0 to 1.1×10⁸ Ω·cm at x=0.5, corresponding to an enhancement of more than four orders of magnitude. The high electrical resistivity of Cr³⁺-doped NiZn ferrite is favorable for high frequency applications. The variation of resistivity can be understood by the combination effect of Cr³⁺ substitution and grain size. The electric transport mechanism in ferrites has been interpreted by the electron hopping between ions of the same element with different valence states on octahedral sites [26], such as the most common case of Fe²⁺/Fe³⁺ randomly located on octahedral sites. The Cr³⁺ ion has a strong preference towards occupying the octahedral sites. The replacement of Fe³⁺ by Cr³⁺ in NiZn ferrite reduces the number of Fe³⁺ on octahedral site. Since the chromium ions do not contribute to the conduction process due to its stable valence state [27], the number of electrons hopping between Fe²⁺ and Fe³⁺ decreases, leading to an enhanced resistivity. However, abnormal decrease of electrical resistivity at x=0.2 and 0.3 is observed. The electrical properties of ferrites are also strongly dependent on the grain boundaries, defects, porosity and stoichiometry. It is known that the inhomogeneous dielectric structure of ferrite ceramic is composed of conductive grains and insulating grain boundaries [28,29]. Previous reports indicated that an increase in density of grain boundaries in a ferrite system increases the electrical resistivity of the system [19,27]. From Fig. 3, it is observed that the grains grow rapidly and merge together for x=0.2 and 0.3 samples. Larger grain size indicates less number of insulating boundaries, which is beneficial to the current flow across the sample. Moreover, the larger grain size means larger surface contact area which promotes the electron flow. Other factors such as porosity and stoichiometry may also contribute to the electric properties, since the unusual grain growth reduces the porosity of the samples. Therefore, the major reason for the decrease in electrical resistivity for x=0.2 and 0.3 samples is ascribed to the decline of grain boundary density due to grain growth. In contrary, x=0.4 and 0.5 samples show a smaller grain size with pore structure, which contains greater number of insulating grain boundaries that hinder the transport of electrons, leading to the high resistivity.

Fig. 6 J-V curves of Ni_0.5Zn_0.5Fe_2-xCr_xO₄ measured at room temperature (a) and electrical resistivity of Ni_0.5Zn_0.5Fe_2-x- Cr_xO₄ deduced from J-V curves (b)

3.5 Dielectric properties

NiZn ferrite is an important kind of dielectric materials [30]. The variation of dielectric constant (ε) for Cr-doped NiZn ferrites as a function of measured frequency in the range from 100 Hz to 1 MHz at room temperature is presented in Fig. 7(a). For the low doping samples, a colossal dielectric constant in the order of 10³-10⁵ appears at low frequencies, which may be attributed to the interfacial polarization correlated with the inhomogeneity of the conductivity between grains and grain boundaries [31]. Similar phenomenon was observed in Ho- and Sm-doped Ni ferrites [32]. The dielectric constant continuously decreases with rising measured frequency, showing a normal dielectric dispersion behavior. It is reported that the dielectric relaxation and conductivity in ferrites have similar activation energies, implying an inherent correlation between these two processes in ferrites [33]. The dielectric polarization process can be understood by the electron hopping conduction between ferrous and ferric ions. Electric dipoles are induced due to the electron hopping between Fe²⁺ and Fe³⁺ ions when alternating electric field is applied, resulting in an electric polarization in the ferrites. However, the hopping process of charge carriers gradually gets out of sync with the frequency of applied alternating electric field, rendering the reduction of dielectric constant. According to the Koops theory [28], the dispersion behavior of dielectric constant was ascribed to the relaxation of interfacial polarization at grain boundaries, in which conductive grains contribute to the high-frequency response and grain boundaries dominate the colossal low-frequency response. The compositional dependence of dielectric permittivity measured at 10 kHz is presented in Fig. 7(b). A strong relevance between dielectric constant and electrical resistivity behavior of ferrite can be observed by comparison with Fig. 6(b). It is found that the high electrical resistivity sample manifests the lower dielectric constant, further supporting the inherent correlation between the polarization process and conduction process in ferrites. The dielectric constant is suppressed with increasing Cr concentration, originating from the reduced Fe²⁺/Fe³⁺ electric dipole number by doping. The abnormal increase of dielectric constant for x=0.3 sample is consistent with its low resistivity, which strongly correlates with its large grain size with less insulating grain boundaries.

Fig. 7 Frequency dependence of dielectric constant for Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites (a) and compositional dependence of dielectric constant for Ni_0.5Zn_0.5Fe_2-x- Cr_xO₄ ferrites measured at 10 kHz (b)

The dielectric tangent loss (tan δ) is an important parameter reflecting the energy dissipation during polarization process, as demonstrated in Fig. 8(a). It is observed that the tangent loss systematically reduces with increasing measured frequency. A tangent loss peak is observed for x=0.3 sample at the frequency about 300 kHz, which can be attributed to the hopping frequency of electron between Fe²⁺ and Fe³⁺ equals to the frequency of the applied field [21]. For x=0.4 and 0.5 samples, the tangent loss value is largely suppressed compared with those low doping samples, especially at high frequencies, implying its potential application in high frequency devices. The tangent loss as a function of chromium concentration is presented in Fig. 8(b), which decreases with increasing chromium doping.

Fig. 8 Frequency dependence of dielectric tangent loss for Ni_0.5Zn_0.5Fe_2-xCr_xO₄ ferrites (a) and compositional dependence of dielectric tangent loss for Ni_0.5Zn_0.5- Fe_2-xCr_xO₄ ferrites measured at 10 kHz (b)

4 Conclusions

(1) The polycrystalline Ni_0.5Zn_0.5Fe_2-xCr_xO₄(0≤x≤0.5) ferrites were prepared by solid state reaction method. Well crystallized single-phase spinel structure without impurity phase for all the prepared samples were confirmed by X-ray powder diffraction technique. The crystal parameter and crystallite size decrease monotonously with the addition of chromium content.

(2) SEM results show the compact and dense microscopic morphology structure of these ferrites. EDS mapping indicates that all elements are evenly distributed in the sample without obvious element aggregation.

(3) Soft ferromagnetic hysteresis loops with tiny coercive field are observed for all the compositions at room temperature. Chromium substitution leads to substantial suppression of the saturation magnetization.

(4) Normal dielectric dispersion behavior is observed for all the compositions in which the permittivity decreases with increasing frequency. The compositional dependence of electrical resistivity is enhanced with chromium substitution, while the dielectric constant shows the opposite tendency.

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