Colossal Permittivity Characteristics of (Nb, Si) Co-Doped TiO2 Ceramics.

(Nb5+, Si4+) co-doped TiO2 (NSTO) ceramics with the compositions (Nb0.5Si0.5)xTi1-xO2, x = 0, 0.025, 0.050 and 0.1 were prepared with a solid-state reaction technique. X-ray diffraction (XRD) patterns and Raman spectra confirmed that the tetragonal rutile is the main phase in all the ceramics. Additionally, XRD revealed the presence of a secondary phase of SiO2 in the co-doped ceramics. Impedance spectroscopy analysis showed two contributions, which correspond to the responses of grain and grain-boundary. All the (Nb, Si) co-doped TiO2 showed improved dielectric performance in the high frequency range (>103 Hz). The sample (Nb0.5Si0.5)0.025Ti0.975O2 showed the best dielectric performance in terms of higher relative permittivity (5.5 × 104) and lower dielectric loss (0.18), at 10 kHz and 300 K, compared to pure TiO2 (1.1 × 103, 0.34). The colossal permittivity of NSTO ceramics is attributed to an internal barrier layer capacitance (IBLC) effect, formed by insulating grain-boundaries and semiconductor grains in the ceramics.

1. Introduction

Titanium dioxide (TiO2) is an interesting inorganic material used in several important applications such as photocatalysis, gas sensing and medical applications, due to its chemical stability at room temperature and its wide band gap [1]. The room temperature relative permittivity (ε′) of pure TiO2 is ~100, which is not suitable for practical energy storage applications. Interestingly, recent studies reported colossal relative permittivity (CP) for co-doped TiO2 in the form (A, B)xTi1−xO2, where A is pentavalent and B is tri- or bivalent cations [2,3,4,5,6]. The origin of CP of the co-doped TiO2 ceramics is controversially discussed in the literature. Several models were proposed to explain the colossal relative permittivity and low dielectric loss (tanδ = ε″/ε′, where ε′ and ε″ are the real and imaginary part of the complex relative permittivity) of co-doped TiO2. It seems there is no universal model that can be applied for all cases. For example, the electron-pinned defect dipole (EPDD) model was successful for (Nb5+, In3+) co-doped TiO2 [7,8,9,10]. This model suggests that the electrons produced by the donors (Nb5+) would reduce Ti4+ to Ti3. In these conditions, defect complexes such as the triangular shaped are created in the rutile structure of TiO2 and are able to inhibit the free electrons from long-range motion. Therefore, CP and low tanδ were expected for these co-doped TiO2. In addition to the EPDD model, the internal barrier layer capacitance (IBLC) model [11,12] has also been suggested as a possible reason for the colossal permittivity of (donor, acceptor) co-doped TiO2 [2,13]. The IBLC model is widely accepted for the interpretation of CP of electrically heterogeneous ceramics. In IBLC, conducting grains are separated by the electrically insulating grain-boundaries. The applied alternating voltage on the sample displaces the charge carriers from the semiconductor grains where they pile up at the thin resistive grain boundaries. The capacitors, thus formed, lead to a colossal effective relative permittivity (ε′) of the ceramic. Considering the IBLC model, the use of acceptors is not compulsory in order to obtain CP in co-doped TiO2. For example, Yang et al. reported on the colossal permittivity in (Nb5+, Zr4+) co-doped TiO2 [14]. Doping of CCTO with SiO2 has been reported as promoting the dielectric properties of CCTO, due to abnormal grain growth [15]. Doping of NiO with Si4+ was effective in increasing the grain boundary resistance due to the formation of a Si-rich secondary phase at the grain-boundaries, which resulted in decreasing the dielectric loss in co-doped NiO ceramics [16]. The phase purity of co-doped TiO2 is dependent on the solubility of dopants in TiO2, which can be predicted by the Hume–Rothery rule [14,17]. According to this rule, a substitutional-solid solution is more likely to form if the difference between the ionic radius of the doping element and the matrix element is less than 15%. In cases where an ionic radius mismatch is greater than 15%, the formation of an interstitial solid solution is more favorable. Most studies opted to choose dopants of ionic radii close to the Ti4+ to avoid the formation of a secondary phase in the prepared ceramics. Nevertheless, the effect of a secondary phase on the dielectric properties of ceramics with a targeted crystalline phase is not easy to predict in most cases [18,19]. The smaller ionic radius of Si4+ (radius = 40 pm) compared to Ti4+ (radius = 60.5 pm) would result in a secondary phase in the resulting ceramics. In the present work, we investigated the dielectric and structural properties of (Nb0.5Si0.5)xTi1−xO2 (x = 0, 0.025, 0.050 and 0.1) over a wide range of frequencies and temperatures. It was found that NSTO ceramics have improved dielectric performance compared to pure TiO2 while the sample (Nb0.5Si0.5)0.025Ti0.975O2 ceramic showed the best improved dielectric performance.

2. Experiment Procedure

2.1. Materials

Anatase TiO2 (99.8%, Aldrich, St. Louis, MI, USA), Nb2O5 (99.99%, Aldrich) and SiO2 (99.99%, Aldrich) were used for the synthesis of the powder of (Nb0.5Si0.5)xTi1−xO2, x = 0, 0.025, 0.050 and 0.1. These samples will be referred to as NSTO.

2.2. Synthesis of (Nb0.5Si0.5)xTi1−xO2 Ceramics

Stoichiometric amounts of the elemental oxides were weighed according to the molar ratio of (Nb0.5Si0.5)xTi1−xO2, then milled in a Retsch PM400 machine for 20 h with a rotation speed of 200 rpm using pots and balls made of tungsten carbide. The obtained powder was pressed (320 MPa) into pellets, 10 mm in diameter and 2 mm in thickness. Subsequently, the pellets were sintered in air inside an electric tubular furnace at a temperature of 1500 °C for 10 h.

2.3. Characterization Methods

Field-emission scanning electron microscope (FE-SEM) (Joel, Tokyo, Japan, SM7600F) and powder X-ray diffraction (XRD) (Stoe and Cie GmbH, Darmstadt, Germany, Cu Kα1 radiation) techniques were used to study the morphology and phase purity of the prepared ceramics. XRD measurements were taken across the range 20° ≤ 2θ ≤ 80° with steps of 0.02°. Raman spectra were recorded with a fully integrated confocal Raman microscope (HORIBA Scientific, Piscataway, NJ, USA) in a back-scattering configuration. All the samples were excited by a He-Cd laser (wavelength 442 nm, 100 mW). The number of gratings in the Raman spectrometer was 1800 L/mm. Impedance spectroscopy (IS) measurements were conducted in dry a nitrogen atmosphere using the system turnkey concept 50 from Novocontrol in the temperature range 200–400 K over the frequency range 1 Hz–1 MHz at an oscillation voltage of 0.1 V. The temperature of the sample was automatically controlled by Quatro Cryosystem. Silver paint was applied to both sides of each pellet before the electrical measurements were taken.

3. Results and Discussion

The XRD patterns of the sintered NSTO ceramics are shown in Figure 1. All the samples present the tetragonal rutile TiO2 (JCPDS 21-1276) as the main phase. The lattice parameters as well as the cell volume were calculated for each sample from the angle and hkl values of the main diffraction peaks using UNITCELL software. These values are summarized in Table 1. Compared to the un-doped TiO2, (Nb, Si) co-doped ceramics (x > 0) show higher values for lattice parameters and the cell volume. These results highlight the effect of the substitution of small Ti4+ ions (radius = 60.5 pm) by the larger Nb5+ ions (radius = 64 pm) in the TiO2 matrix. Moreover, a tiny impurity peak is observed in the XRD of doped samples at 21.82° and corresponds to SiO2 (JCPDS 47-718). Compared to the (110) peak of the main TiO2 rutile phase, the intensity of the impurity peak is considerably low, but increases with increasing the doping content.

Figure 1

The XRD patterns of the sintered NSTO ceramics.

Table 1

Lattice parameters and volume cell for NSTO ceramics.

	Lattice Parameters (Å)		Cell Volume (Å3)
	a	c
x = 0	4.59264	2.95668	62.3634
x = 0.025	4.59703	2.95852	62.5214
x = 0.05	4.59669	2.95655	62.4706
x = 0.01	4.60647	2.96170	62.8476

Raman spectroscopy is known for its usefulness in confirming the anatase or rutile phase of TiO2 [20]. Figure 2 represents the room temperature Raman spectroscopy over the range of 100–1100 cm−1 for NSTO ceramics. Four peaks are observed at ~143 cm−1, ~447 cm−1, ~612 cm−1 and ~826 cm−1. These peaks correspond to the typical first-order Raman-active modes of rutile TiO2: B1g, Eg, A1g and B2g, respectively [21]. In addition, a peak is observed at ~237 cm−1, which is a second-order scattering feature [21]. Therefore, Raman spectroscopy confirmed that all NSTO ceramics possess the rutile phase structure, which is in agreement with the XRD results. As seen in Figure 2, the Eg slightly shifted toward a lower wave number for the sample with x = 0.1, which might be due to the evolution of lattice distortion and the movement of oxygen along c-axis with the increase in dopants content [22].

Figure 2

Raman spectra of the sintered ceramics of NSTO.

Figure 3 shows FE-SEM micrographs of the scratched surface of NSTO ceramics. The grains and grain-boundaries are clearly seen for all the samples. Using the lineal intercept method [23,24], the average grain size was found to be 9.1 ± 1.6, 5.6 ± 1.1, 4.8 ± 0.9 and 9.4 ± 1.6 µm for the samples with x = 0, 0.025, 0.05 and 0.1, respectively. Therefore, the average grain size tends to decrease with increasing the dopants content up to x = 0.05. Additionally, the grain in the co-doped samples seems to be composed of smaller sub-grains as shown by the red-dashed line in the SEM micrograph of the sample x = 0.025 (Figure 3). Similar observations on the effect of doping content on the grain size have been reported [25,26,27]. This behavior was attributed to the effect of the secondary phase in inhibiting grain growth [25] and/or the increased number of nuclei centers with increasing doping content [27].

Figure 3

FE-SEM morphology of NSTO ceramics.

Figure 4 shows the frequency dependency of relative permittivity (ε′) and dielectric loss (tanδ) of NSTO ceramics. It can be seen that (Nb, Si) co-doped TiO2 (x > 0) ceramics have improved dielectric properties in terms of higher ε′ and lower tanδ compared to the un-doped sample (x = 0). Among these ceramics, the sample with x = 0.025 showed the minimum tanδ of ~0.11 and colossal permittivity (ε′~4.8 × 104) at 10 kHz and room temperature. This dielectric performance is close to that of (Nb, La) [25], (Ta, In) [6] and (Nb, Eu) [28] co-doped TiO2 but lower than (Ta, Mg) [29], (Ta, Y) [30] (Ta, Ho) [31] (Nb, Zr) [14] co-doped TiO2.

Figure 4

Frequency dependence of ε′ and tanδ at room temperature for NSTO ceramics.

Figure 5 depicts the room temperature complex impedance (Z* = Z′ + iZ″) plots for the four ceramic samples. The impedance spectrum of every sample is comprised of a large semicircular arc that covers most of the frequency range. However, a close examination at the high-frequency region reveals that the aforementioned arc does not pass through the origin. A second circular arc and non-zero intercept with the real Z′ axis is observed in the high frequency region for the samples with x = 0 and x > 0, respectively. This behavior is similar to what is reported for CaCu3Ti4O12 [32] and co-doped TiO2 [2,13]. The arc at high frequency (/non zero intercept) is attributed to the response of the semiconductor component (grains), while the larger arc represents the response of electrically insulating component (grain-boundaries). The resistances of grains (Rg) and grain-boundaries (Rgb) can be calculated from the intercepts of the corresponding arcs with the axis of the real part of the impedance (Z′) [11]. The room temperature values of Rg and Rgb are summarized in Table 2. It can be seen that the NSTO ceramics have an electrically heterogeneous structure of semiconducting grains and resistive grain-boundaries. It is observed that the change in Rgb with increasing doping content is more pronounced than in Rg. This result indicates that (Nb5+, Si4+) co-doping affects, principally, the grain-boundary resistance of TiO2. Moreover, Rg and Rgb decrease gradually with increasing doping content because of the increase in the concentration of free carriers as a result of doping. The sintering temperature is reported to affect the dielectric performance of pure rutile TiO2 [18,33,34]. For example, ε′ was found to increase from 400 to 1.3 × 104 with increasing the sintering temperature from 1200 to 1450 °C [33]. In our case, the undoped TiO2 has a performance comparable to that found in the literature for the rutile TiO2, which is sintered at high temperature [18]. In this reference, the dielectric constant and tanδ of pure TiO2 ceramics at 1 kHz and room temperature were found to be 103 and ~0.4, respectively. As seen in Figure 4, the co-doped NSTO samples (x > 0) have comparatively higher relative permittivity (ε′) and lower dielectric loss (tanδ), in the frequency range > 103 Hz, than the pure TiO2 (x = 0). As shown by the FE-SEM micrograph in Figure 3, the grain of the co-doped ceramic is composed of smaller grains. Therefore, we believe that the co-doping results in more grain-boundary barriers in front of the charge carriers, which causes the reduced tanδ values for co-doped ceramics in the high frequency range.

Figure 5

Impedance complex plane plot (Z*) at room temperature for NSTO ceramics.

Table 2

The room temperature values of grain resistivity (Rg), grain-boundary resistivity (Rgb), ε′ and tanδ at 1.1 kHz and the minimum dielectric loss value (tanδ)min for NSTO ceramics.

	Rg (Ω.cm)	Rgb (Ω.cm)	ε′	tanδ	(tanδ)min
			at 1.1 kHz
x = 0	1.2 × 104	9.0 × 106	1.1 × 103	0.65	0.34 (at 58 Hz)
x = 0.025	15.3	3.0 × 105	5.5 × 104	0.18	0.11 (at 10 KHz)
x = 0.05	9.7	1.0 × 105	6.0 × 104	0.40	0.11 (at 24 KHz)
x = 0.1	35.9	4.3 × 104	5.3 × 104	1.37	0.13 (at 47 KHz)

Figure 6 shows the variation in the imaginary part of the impedance (Z″) with frequency at selected temperatures for NSTO ceramics. At a given temperature, the spectrum of Z″ shows a peak with maximum value at a frequency fmax. With increasing temperature, decreases while fmax shifts to higher frequencies. According to the inter barrier layer capacitance (IBLC), the dependence of the imaginary part of the impedance (Z″) on the angular frequency (ω) is given by [35,36]: where Rg (/Rgb) and Cg (/Cgb) are the resistances and capacitances of the grain (/grain-boundaries), respectively. Consequently, for electrically heterogeneous materials with Rgb >> Rg, the overall resistance of the sample R ≈ Rgb and can be calculated from by the relationship:

Figure 6

Frequency dependence of −Z″ at different temperatures for NSTO ceramics.

Moreover, the relaxation time (τ) is related to the frequency fmax by the relationship:

The activation energy for conduction (E) and for relaxation (U) were calculated from the Arrhenius plots in Figure 7 using the relationships: where σ0 is the pre-exponential factor, KB is Boltzmann constant and T is absolute temperature. where τ0 is the pre-factor and U is the activation energy for the relaxation process.

Figure 7

The Arrhenius plots of the conductivity σ (left) and relaxation time τ (right) in the grain-boundaries for NSTO ceramics. The dashed line represents the line of best fit.

The calculated values of activation energies from the spectra of M″ are given in Table 3. It can be seen that the co-doped NSTO samples (x > 0) have activation-energy values considerably lower than the pure TiO2 (x = 0), which correlate with the lower resistivity of these samples.

Table 3

Activation-energy values for conduction (E) and for relaxation process (U) for NSTO ceramics.

	E(eV)	U(eV)
x = 0	0.338	0.341
x = 0.025	0.089	0.095
x = 0.05	0.087	0.078
x = 0.1	0.101	0.099

Moreover, the modulus formalism has been deployed to further study the conductivity relaxation behavior of the NSTO ceramics. Figure 8 shows the spectra of the imaginary part M″ of the electric modulus M* = M′ + iM″ = 1/ε*, where ε* is the complex relative permittivity. At room temperature, the spectrum of M″ of the un-doped TiO2 (x = 0) shows two resolved peaks. For the co-doped samples (x > 0), only the low frequency peak is observed within the studied frequency range. The low and high frequency M″ peaks are attributed to the contribution of grain-boundary and grain, respectively. Furthermore, the observed peaks shift towards higher frequency with increasing temperature. The relaxation time τ is related to the peak frequency (fmax) as τ = 1/2πfmax. The insets of Figure 4 show the log(τ) versus 1000/T curves, which are fitted according to the Arrhenius equation. The calculated activation energy of the grain-boundary is 0.351 eV, 0.093 eV, 0.089 eV and 0.112 eV for the samples with x = 0, 0.025, 0.05 and 0.1, respectively. These values are comparable to the activation energies obtained from the spectra of Z″, as previously presented in Table 3.

Figure 8

Frequency dependence of M′′ at different temperatures for NSTO ceramics.

The activation-energy values for the doped ceramics (x > 0) are comparable to the value of 0.1 eV reported for the dipolar relaxation due to electrons hopping between Ti3+ and Ti4+ ions in co-doped TiO2 [37]. Substituting of Nb5+ for Ti4+ resulting in a distorted lattice and the reduction of some Ti4+ to Ti3+. This process may be expressed using Kroger-Vink notations as follows [38,39]:

4. Conclusions

(Nb0.5Si0.5)xTi1−xO2, (x = 0, 0.025, 0.050 and 0.1) (NSTO) ceramics were fabricated using a conventional, high-temperature, solid state reaction technique. X-ray diffraction (XRD) patterns and Raman spectra confirmed that the tetragonal rutile is the main phase in all the ceramics. Additionally, XRD revealed the presence of a small amount of secondary phase of SiO2 in the co-doped ceramics. NSTO ceramics showed room temperature colossal relative permittivity (>104) over the studied frequency range (1–1 MHz). (Nb, Si) co-doped (Nb0.5Si0.5)0.025Ti0.975O2 ceramics showed the most improved dielectric performance as higher ε′ (~5.5 × 104) and lower tanδ (~0.18), at 10 kHz and 300 K, compared to pure TiO2 (1.1 × 103, 0.34). The colossal permittivity of NSTO ceramics is attributed to an internal barrier layer capacitance (IBLC) effect, formed by insulating grain-boundaries and semiconductor grains in the ceramics. The electrical heterogeneity of the NSTO ceramics was confirmed by the impedance-spectroscopy analysis. The activation-energy values for conduction and relaxation of the co-doped NSTO ceramics are close to 0.1 eV which is reported for the dipolar relaxation due to electrons hopping between Ti3+ and Ti4+ ions in co-doped TiO2