1. Introduction

The interesting physical properties of relaxor ferroelectrics that exhibit diffusion during phase transitions have gained considerable attention, as they have practical potential for applications such as electrostrictive components [1], PTCRs (positive temperature coefficient resistors) [2,3], multilayer ceramics capacitors (MLCCs) [4] and multicaloric applications [5]. Classic ferroelectrics can be transformed into relaxor ferroelectrics (RFEs) by means of a doping strategy, such as BaTiO₃ (BT)-based [6], (Na_0.5 Bi_0.5)TiO₃ (NBT)-based [7,8] and other traditional ferroelectric systems [9,10].

The effects of doping with various oxides in classic ferroelectric materials have been extensively studied by many researchers. It was found that the Curie temperature (TC) becomes higher as NBT is added in BT-based ceramics [11]. For example, the Curie temperature increases from 125 to 156 °C with 8 mol% NBT added into BT, making it possible to satisfy the MLCC criterions [12]. The trivalent rare earth ions and manganese ions were found to be effective for the improvement of the temperature-dependent permittivity of BaTiO₃ dielectrics [13,14]. However, the addition of the trivalent (La³⁺, Y³⁺) [15,16,17,18] donor dopants cause an increase in room-temperature conductivity. Ding et al. reported that the resistance of BT ceramics decreases with Y doping and increases dramatically with Mn doping. Gong et al. studied the resistance degradation and the conduction mechanism of Mn-doped nano-BaTiO₃ ceramics. They found that the resistivity reliability characteristics greatly depended on the Mn ions. Incorporating 0.3 mol% of manganese has a positive impact on enhancing the reliability of BaTiO₃-based ceramics, which is a crucial factor for the application of multilayer ceramic capacitors (MLCCs). Mn-doping at the Ti site in BT has been extensively studied by several groups [19,20,21,22], and it was found that the Mn acts as an acceptor, which improves the electrical resistivity near the Curie temperature. Furthermore, Mn²⁺ or Mn⁴⁺ ions as acceptor dopants were found to be located at the grain boundaries to enhance the PTC effect [23,24]. In summary, it was found that the rare earth (Ln) oxides are effective dopants in BT-based ferroelectric materials and lead to a broader ε_r′-T dispersing curve. However, ferroelectric relaxors based on Ln-doped BT often exhibit low resistivity and high dielectric loss [14,25,26], which results in high energy consumption in devices made from these materials. Since the dielectric loss in ferroelectric relaxors is mainly caused by electric conduction, samples with higher resistivity generally exhibit lower dielectric loss. Therefore, it is expected that co-doping Mn and Ln could modify both the temperature-dependent permittivity dispersion and dielectric loss (resistivity) of BT-NBT ferroelectric relaxors, leading to the development of ferroelectric relaxors with lower dielectric loss.

In this paper, Mn-Yb co-doped BT-NBT ceramic samples were designed and synthesized. Using X-ray diffraction, SEM, LCR meter and AC impedance measurements, we analyzed the microstructure, dielectric relaxation behavior and electrical properties, particularly the resistivity and dielectric loss behavior. The results indicate that the co-doping of Mn-Yb in BT-NBT leads to the production of a low-loss ferroelectric relaxor.

2. Materials and Methods

The conventional solid-state reaction method was used to prepare the 0.92BT-0.08NBT-0.02Yb-xMn (x = 0.0025, 0.005, 0.01, 0.015, 0.02) (BT-NBT-Yb-xMn) ceramic samples. After pre-synthesizing NBT powder from reagent-grade Na₂CO₃, Bi₂O₃ and TiO₂ calcined at 800 °C for 2 h, BT and NBT powders were mixed in a mole ratio of 0.92:0.08. The slurries were dried and calcined at 900 °C for 2 h, resulting in the formation of a BT-NBT solid solution, and then mixed with 0.02 mol Yb₂O₃ and x mol MnCO₃ in ethanol, and ball-milled with zirconium media for 24 h. After drying, the powders were added to 4 wt.% polyvinyl alcohol (PVA) as a binder and pressed into pellets. The compacts were sintered at a temperature range of 1230–1280 °C for 2 h, followed by meticulous polishing of the resulting ceramics.

To determine the phase composition and lattice parameters, X-ray powder diffraction (XRD) was carried out using Cu Kα radiation (X’Pert PRO, PANalytical, Almelo, The Netherlands). The microstructures of the ceramics were examined using SEM (JSM-5610LV, JEOL, Tokyo, Japan). The pellets with dimensions of 10 mm (diameter) and 1 mm (thickness) were coated with Ag paste as electrodes on both sides for dielectric measurement. Temperature-dependent capacitance and dielectric loss were measured with an LCR meter (HP E4980A, Palo Alto, Santa Clara, CA, USA) at 1 KHz, 10 KHz, 100 KHz and 200 KHz, from room temperature to 200 °C. For the measurement of electrical properties, the Pt paste was pasted on ceramic samples as electrodes. Impedance spectra were measured for the ceramics in the frequency range of 10⁻² to 10⁶ Hz, from room temperature to 700 °C using a Solartron 1260 impedance/grain-phase analyzer and 1296 dielectric interface. Impedance results were analyzed using ZView software(v3.0a).

3. Results and Discussions

3.1. Structural and Microstructural Study

The phase of the samples was determined by X-ray diffraction analysis, and the corresponding patterns are presented in Figure 1a for the BT-NBT-Yb-xMn ceramics. The samples gave similar XRD patterns, which match the BT tetragonal phase [27], and no obvious impurity reflections were observed. A single-phase perovskite structure with tetragonal symmetry was exhibited with the sample x = 0.015, showing a distinct peak splitting of (002) and (200) peak at around 45° in the 2θ range representing a normal tetragonal structure, but the peaks overlap each other in other samples representing a pseudo-cubic structure, which means it is hard to recognize the tetragonal phase or cubic one from the peak splitting. The lattice parameters and tetragonality utilizing the Pawley refinements program in the as prepared samples are shown in Figure 1b,c. Both the a and c increase with the increase of x and reach the maximum as x = 0.015, which means that a solid solution was formed at x ≤ 0.015. Referring to the ionic radii of Mn and Ti⁴⁺ in the octahedra [coordination number CN = 6, R(Mn²⁺) = 0.83Å, R(Mn³⁺) = 0.58Å, R(Mn⁴⁺) = 0.53Å, R(Ti⁴⁺) = 0.61Å)] [28], it can be inferred that the Mn in the solid solution should be Mn²⁺ and B-O bonds (B = Mn, Ti) become longer as Mn²⁺ is added. The tetragonality (c/a) of the samples gradually increases from 1.0085 for x = 0.0025 to 1.0095 for x = 0.01, and then decreases to 1.0072 for x = 0.02. Notably, the tetragonality (c/a) values are quite close to the ideal cubic condition with c/a = 1.000, leading to the definition of the samples as pseudo-cubic phase. As the ionic radii of Mn and Ti⁴⁺ differ, Mn causes more significant distortions in [BO₆] (B = Mn or Ti) octahedra than in the original BT-NBT-Yb. This is expected to affect the diffusion in the phase transition (dielectric relaxing) of the samples [29].

Figure 2a–e shows the SEM images of fractured surfaces of sintered BT-NBT-Yb-xMn ceramics. All specimens show similar microstructures with an average grain size of about 1 µm. It is clear that the Mn does not affect the average grain size of BT-NBT-Yb-xMn ceramics.

3.2. Dielectric Relaxation

The temperature-dependent permittivity and the dielectric loss (tanδ) of BT-NBT-Yb-xMn from LCR measurements are shown in Figure 3. As Mn was doped into the samples, the dielectric loss (tanδ) of all BT-NBT-Yb-xMn samples are all lower than 0.1. The dielectric loss is obviously lower than that of samples without Mn [26], which generally give a tanδ of ~0.3. Sample BT-NBT-Yb-0.01Mn gives the low dielectric loss tanδ < 0.05, and samples with x ≤ 0.01 are close to each other. The temperature-dependent permittivity curve is strongly affected by the composition. There are two clear characteristic dielectric peaks. For the permittivity at 1 KHz, the permittivity of peak A increases from 2379 at 147 °C for x = 0.0025 to 2875 at 138 °C for x = 0.01, then decreases to 1742 at 135 °C for x = 0.02. The permittivity of peak B decreases from an obvious band at x ≤ 0.005 to a weak shoulder (x = 0.01), and then to a plateau (x = 0.02). The permittivity of peak B decreases with increasing frequency and the corresponding temperature shifts to higher temperatures as x = 0.01, which is a typical relaxor behavior of ceramic. On the other hand, the permittivity of peak B shows a very broad peak for x = 0.02. The broadening peak observed in the temperature dependence of the permittivity of BT-NBT-Yb-xMn ceramics was confirmed to be a relaxor, which exhibits a slow phase transition along with a strong dispersion of the temperature of maximum dielectric permittivity against frequency.

According to the XRD results, the tetragonality changes with the composition and should be the origin of classical ferroelectric behavior, in which a higher tetragonality c/a should give a larger permittivity. Combing the XRD and permittivity results, the permittivity is expected to show a maximum at x = 0.01. The change of permittivity of peak A is consistent with the change of tetragonality very well, which means that the permittivity of peak A is dominated by the main phase. However, the permittivity of peak B is almost independent of the tetragonality c/a, which means that one is controlled by the other factors (microstructure).

Several factors have been identified in the literature that play an important role in the variation of temperature-dependent permittivity (diffused phase transition). These include cation ordering and internal stresses. Alkathy et al. reported that in Bi- and Li-co-doped BaTiO₃, grain size distribution is a significant factor affecting the diffuse character of the dielectric permittivity peak. As the concentrations of Bi and Li increased, the average grain size decreased, and diffusivity increased [30]. Armstrong et al. showed that the permittivity of BaTiO₃ modified with 2 wt% ZrO₂ resulted in a suppressed ferroelectric transition region. They attributed this to the unique microstructure of core–shell grains and mismatch internal stress between the core and shell regions, leading to a flat temperature-dependent permittivity [31]. Furthermore, Yung et al. investigated how stress affects the dielectric temperature properties of cerium-modified barium titanate. By using TEM, they observed three different inhomogeneous regions, including grain core, grain shell and gradient regions, and they explained how the dielectric temperature characteristics are related to the regions and internal stress [32]. As the average grain size of BT-NBT-Yb-xMn ceramics is not affected by the doping of Mn from SEM analysis, the change of temperature-dependent permittivity in BT-NBT-Yb-xMn should be caused by the inhomogeneous regions of grain core, grain shell, gradient ones and internal stress. As indicated by SEM analysis, the doping of Mn does not affect the average grain size of BT-NBT-Yb-xMn ceramics. Therefore, the changes in the temperature-dependent permittivity of BT-NBT-Yb-xMn can be attributed to inhomogeneous regions with the grain core, grain shell and gradient ones, as well as internal stress.

3.3. Impedance Analysis

The impedance Z* plots for all samples in a wide temperature (100–600 °C) are measured and shown in Figure 4. At low temperatures (≤200 °C), each sample exhibits a single or partial semicircle, indicating a response attributed to the grain. This suggests that the grain provides high resistance, which is advantageous for minimizing dielectric loss associated with low leakage current. There are two overlapping arcs observed at T ≥ 300 °C for samples with x ≤ 0.01, which are from the grain and grain boundaries of the ceramics. However, there was only grain arc response observed for samples with x ≥ 0.015.

The normalized Z″ and M″ against frequencies at selected temperatures are plotted in Figure 5. With the increase in temperature, the maximum Z″_max and M″_max shift to the higher frequency. The similar frequency of the Z″_max and M″_max peaks indicate that the relaxation describes the same response. The Z″ shows two relaxation peaks for the lower Mn-doped compounds (x ≤ 0.01, Figure 5a–c) in which the peak at a lower frequency and the other at a higher frequency are from the relaxation process of grains and grain boundaries, respectively. However, in the samples with x = 0.015 and x = 0.02, both the Z″ and M″ show one peak at a close frequency, which is dominated by the grain response.

The temperature-dependent Z″ and M″ peak frequencies of samples are presented in Figure 6. Using the Arrhenius equation, the activation energy of both the grain and grain boundaries in BT-NBT-Yb-xMn ceramics were determined through calculations based on the imaginary part of the modulus and impedance.

${\omega }_p\left(T\right)=2\mathsf{\pi }{f}_p\left(T\right)=Aexp\left(\frac{-E_a}{kT}\right)$

3.4. Frequency Dependent ε_r′ and ε_r″

The real part of permittivity (ε_r′) as a function of frequency at different temperatures of the BT-NBT-Yb-xMn ceramic is shown in Figure 7a–e. At very low frequencies, the ε_r′ increases for all samples as the temperatures increase. At temperatures 200–700 °C, there are broad dispersed steps with relatively high permittivity observed in the low frequency region and the step shifts to a higher frequency with the increase of temperature. This behavior is associated with a frequency-dependent orientational polarization. For x = 0.0025, high dielectric permittivity (at ≤10 Hz) is observed at high temperatures. The ε_r′ at 0.01 Hz is almost two magnitudes of orders larger than that at 10 Hz. This should be caused by extrinsic contributions such as space charge localization at the grain boundaries [33]. The permittivity ε_r′ is almost independent of frequency at low temperatures (≤200 °C) with plateaus for all samples, except slight increases at low frequency (f < 1 Hz) for x = 0.015 and x = 0.02 samples.

For high frequencies, permittivity ε_r′ decreases with the temperature and reaches a plateau. Referring to the impedance analysis, the relative permittivity observed at 10 Hz ≤ f ≤ 10⁶ Hz is caused by the dielectric relaxation from the grain and/or grain boundaries. In addition, the temperature-dependent permittivity (Figure 3) measured from LCR meter is coincident with that from impedance measurements (frequency-dependent curves in Figure 7).

The frequency-dependent tanδ at different temperatures of BT-NBT-Yb-xMn ceramics are shown in Figure 8. The tanδ shows a plateau at temperatures below 100 °C, which is less than 0.06 from 0.01 Hz to 10⁶ Hz and remains almost unchanged with x ≤ 0.005. At 50 °C, the tanδ at 1 KHz are 0.02, 0.02, 0.02, 0.03, 0.02 for x = 0.0025, 0.005, 0.01, 0.015 and 0.02, respectively. The samples show lower tanδ (≤0.06) as x ≤ 0.01, and tanδ increases with x > 0.01. As temperature increases, the samples show a higher tanδ step at a low frequency, and the step shifts to a higher frequency. For example, as x = 0.005, the maximum of tanδ located at the frequency of 3.98 Hz, 251 Hz, 6309 Hz, 50,119 Hz and 39811 Hz at 300 °C, 400 °C, 500 °C, 600 °C and 700 °C, respectively. This can be described as RC resonance at a lower frequency and smaller polarization at a high frequency.

3.5. Resistivity

The temperature-dependent resistivity of BT-NBT-Yb-xMn samples are shown in Figure 9. At room temperature, the resistivity calculated from impedance analysis is ≥3 × 10¹² Ω cm, ≥3 × 10¹² Ω cm, 1.61 × 10¹¹ Ω cm, 3.39 × 10¹⁰ Ω cm and 1.61 × 10¹⁰ Ω cm for x = 0.0025, 0.005, 0.01, 0.015 and 0.02, respectively. At 200 °C, the resistivity is 4.37 × 10¹¹ Ω cm, 5.88 × 10¹¹ Ω cm, 1.86 × 10¹¹ Ω cm, 5.77 × 10¹⁰ Ω cm and 2.91 × 10¹⁰ Ω cm for x = 0.0025, 0.005, 0.01, 0.015 and 0.02, respectively. The resistivity shows a maximum at x = 0.005 and decreases with the increase of Mn. The resistivity of samples with x = 0.005 is about two times higher than that of samples with the BT-NBT-Yb sample. Thus, the doping of Mn shows an obvious increase in resistivity. The activation energy (Ea) calculated is 1.29 eV, 1.31 eV, 1.16 eV, 1.08 eV and 1.01 eV for x = 0.0025, 0.005, 0.01, 0.015 and 0.02, respectively. The activation energies decrease with the increase of Mn, and the samples with x ≤ 0.005 give the highest activation energy (Ea).

As is known, the properties of oxide materials, particularly their electrical resistance, are significantly influenced by the concentration and distribution of oxygen vacancies. It is noteworthy that oxygen vacancies are the defects most commonly found in oxide materials [34]. It was found that Ea for all samples was about 1eV, which is very close to the activation energy of oxygen vacancies [35]. In a BT-NBT-Yb-xMn system, the Mn should be on the Ti⁴⁺ site as an acceptor in the perovskite solid solution of BT-NBT as the ionic radius of Mn²⁺ (0.83 Å as CN = 6 and 0.96 Å as CN = 8) is closer to Ti⁴⁺ (0.61 Å as CN = 6) than Ba²⁺ (1.42 Å as CN = 8 and 1.61 Å as CN = 12) [28]. The neighboring acceptor–oxygen vacancy pairs were formed to maintain electro-neutralization; Mn ions can reduce the oxygen vacancies in the perovskite. With a small amount of Mn addition, it is helpful to improve the insulation resistance of the ceramics. These ceramics are, therefore, well suited for applications as dielectric materials. With higher dopant concentration (x ≥ 0.015), Mn induces the formation of various new defects, which causes a decrease in resistivity [13].

4. Conclusions

A single perovskite-type structure was achieved for BT-NBT-Yb-xMn ceramics prepared via solid-state reaction. The Nyquist plot, complex impedance, complex modulus, resistivity and activation energy of charge carriers were analyzed to study the microstructure–electrical property relationships. The temperature-dependent permittivity shows dielectric relaxations. The small amount of Mn (x ≤ 0.005) causes an obvious decrease in dielectric loss. The BT-NBT-Yb-xMn with x ≤ 0.005 gave the lowest dielectric loss of tanδ ~0.06. The resistivity of BT-NBT-Yb-xMn was >3 × 10¹² Ω cm as x ≤ 0.005 and decreased to 1.61 × 10¹⁰ Ω cm as x = 0.02. The activation energy of charge carriers calculated from the temperature dependence of resistivity decreased from 1.29 eV to 1.01 eV as the x increased from 0.0025 to 0.02.

Footnotes

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Figure 1. (a) XRD patterns of BT-NBT-Yb-xMn samples; (b) cell parameters a and c calculated from the XRD data; (c) the tetragonality c/a from Pawley refinements of all samples.

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Figure 2. SEM images of fractured BT-NBT-Yb-xMn ceramics samples. (a) x = 0.0025, (b) x = 0.005, (c) x = 0.01, (d) x = 0.015, (e) x = 0.02.

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Figure 3. The temperature-dependent permittivity (εr′) and the dielectric loss (tanδ) of the BT-NBT-Yb-xMn samples were measured at frequencies f1 = 1 KHz, f2 = 10 KHz, f3 = 100 KHz and f4 = 200 KHz. (a) x = 0.0025 (b) x = 0.005 (c) x = 0.01 (d) x = 0.015 (e) x = 0.02; A, B denote different peaks of εr′-T.

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Figure 4. Nyquist plots of BT-NBT-Yb-xMn samples at various temperatures. (a) 100 °C, (b) 200 °C, (c) 300 °C, (d) 400 °C, (e) 500 °C, (f) 600 °C.

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Figure 5. The normalized −Z″ and M″ of BT-NBT-Yb-xMn at 200–600 °C. (a) x = 0.0025, (b) x = 0.005, (c) x = 0.01, (d) x = 0.015, (e) x = 0.02. g: grain; gb: grain boundary.

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Figure 6. Temperature-dependent frequency of Z″max and M″max of BT-NBT-Yb-xMn (a) grain boundary and (b) grain.

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Figure 7. Frequency-dependent permittivity (εr′) of BT-NBT-Yb-xMn with Pt electrode at various temperatures. (a) x = 0.0025, (b) x = 0.005, (c) x = 0.01, (d) x = 0.015, (e) x = 0.02.

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Figure 8. Frequency dependent of dielectric loss (tanδ) of BT-NBT-Yb-xMn with Pt electrode measured at various temperatures. (a) x = 0.0025, (b) x = 0.005, (c) x = 0.01, (d) x = 0.015, (e) x = 0.02.

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Figure 9. Temperature-dependent resistivity (ρ) of BT-NBT-Yb-xMn.

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