Investigation on Electrical Properties and Microdefects of Nb<sup>5+</sup>-Doped BaTiO<sub>3</sub> Based Ceramics by Positron Annihilation Techniques

Cheng, Xuxin; Wang, Yuxin; Chen, Xiaoming; Cui, Haining

doi:10.1590/1980-5373-MR-2018-0921

Abstract

The influence of the Nb⁵⁺-doped content and the doping CaCO₃ on the electrical properties and the microdefects of BSTN ceramics by Positron Annihilation Techniques were studied, which were fired at 1350 ºC for 2 hours in air. The PTCR characteristics in the BSTN samples were also investigated. Moreover, the information on microdefects in BSTN ceramics was demonstrated by coincidence Doppler broadening spectrum measurements and positron annihilation lifetime spectra. Meanwhile, the influence of the defects on the electrical properties of the ceramics was also revealed. Furthermore, the critical donor-dopant content was 0.4 mol%, which corresponding room-temperature resistivity and the resistivity jumping ratio was 714.3 Ω·cm and 2.77 × 10², respectively. In addition, the average positrons annihilate lifetime t of the BSTN ceramics was investigated as well.

Keywords:
BaTiO₃; PTC effect; Positron annihilation; Defect; Electroceramics

1. Introduction

Barium titanate is a ferroelectric material, which transforms from a tetragonal perovskite structure (ABO₃) into a paraelectric structure ¹1 Mancini MW, Paulin Filho PI. Direct observation of potential barriers in semiconducting barium titanate by electric force microscopy. Journal of Applied Physics. 2006;100(10):104501.. The ions at the A or B site of BaTiO₃ are replaced by small quantities of a trivalent donor or pentavalent impurities, respectively; BaTiO₃ becomes a semiconducting material and exhibits the positive temperature coefficient of resistivity (PTCR) effect ²2 Illingsworth J, Al-Allak HM, Brinkman AW, Woods J. The influence of Mn on the grain-boundary potential barrier characteristics of donor-doped BaTiO3 ceramics. Journal of Applied Physics. 1990;67(4):2088-2092.^,³3 Heywang W. Resistivity Anomaly in Doped Barium Titanate. Journal of the American Ceramic Society. 1964;47(10):484-490.. Heywang ⁴4 Heywang W. Bariumtitanat als sperrschichthalbleiter. Solid-State Electronics. 1961;3(1):51-58. explained this phenomenon, and an improved discussion was later provided by Jonker ⁵5 Jonker GH. Some aspects of semiconducting barium titanate. Solid-State Electronics. 1964;7(12):895-903.. The PTCR characteristic of doped BaTiO₃ ceramics is considered to a grain-boundary effect.

An effective method is considered to detect defects in bulk by positron annihilation technology (PAT) ⁶6 Pikart P, Hugenschmidt C, Horisberger M, Matsukawa Y, Hatakeyama M, Toyama T, et al. Positron annihilation in Cr, Cu, and Au layers embedded in Al and quantum confinement of positrons in Au clusters. Physical Review B. 2011;84(1):014106.^,⁷7 Wang D, Chen ZQ, Wang DD, Qi N, Gong J, Cao CY, et al. Positron annihilation study of the interfacial defects in ZnO nanocrystals: Correlation with ferromagnetism. Journal of Applied Physics. 2010;107(2):023524., which include the coincidence Doppler broadening spectrum (CDBS) and positron annihilation lifetime spectra (PALS). The momentum distribution of the annihilating e⁺-e′ pairs can be detected using the CDBS; meanwhile, the annihilation information of positrons can be offered by the PALS. Recently, Deng et al. ⁸8 Deng W, Guo JT, Brusa RS, Karwasz GP, Zecca A. Effects of Zr and Nb on d electrons in NiAl alloy studied by coincidence positron annihilation spectroscopy. Materials Letters. 2005;59(27):3389-3392. suggested that the Nb addition was effective in enhancing the d-d interactions by Positron Annihilation Techniques (PAT). The defects of the ZnNb_2−x Ti_x O_6−x ceramics could be also investigated by PAT ⁹9 Tang Y, Zhang Y, Du PY, Deng W. Direct Control of Defects on Positron Lifetimes and Dielectric Constant of Microwave Ceramics. Journal of the American Ceramic Society. 2013;96(8):2537-2543.. The PALS of TiAl alloys had been analyzed ¹⁰10 Deng W, Huang YY, Wu DH, Cao MZ, Xiong LY. Effects of Cr and Sn on defects and electron densities in TiAl alloys. Materials Letters. 2002;56(4):593-596.. In addition, a high amount of titanium vacancies could lead to grain-growth inhibition ¹¹11 Brzozowski E, Castro MS. Grain growth control in Nb-doped BaTiO3. Journal of Materials Processing Technology. 2005;168(3):464-470.. The precipitation of a Ti-rich phase was due to a vacancy-compensation mechanism ¹²12 Langhammer HT, Makovec D, Pu Y, Abicht HP, Drofenik M. Grain boundary reoxidation of donor-doped barium titanate ceramics. Journal of the European Ceramic Society. 2006;26(14):2899-2907.. Thus, the charge compensation was achieved by titanium vacancies and electrons ¹³13 Chan HM, Harmer MR, Smyth DML. Compensating Defects in Highly Donor-Doped BaTiO3. Journal of the American Ceramic Society.1986;69(6):507-510..

However, little attention has been paid to the donor-doped content on both the electrical properties and the microdefects of the BSTN ceramics. Previous studies have focused only on the chemical reaction of the samples. Therefore, the objective of this study is to investigate the effects of the donor-doped content and the doping CaCO₃ on the microdefects and the electrical properties of BSTN ceramics using the PAT.

2. Experimental Procedures

The starting materials were high-purity BaCO₃ (>99.8%), SrCO₃ (>99.8%), Nb₂O₅ (>99.99%), TiO₂ (>99.8%), Al₂O₃ (>99.8%), and SiO₂ (>99.99%), and they were weighed on the basis of the following formula: (Ba_0.95Sr_0.05)(TiNb_x)O₃ + Mn(NO₃)₂ + 0.25 mol% (4Al₂O₃: 9SiO₂: 3TiO₂) (BSTN), In our work, the samples doped with 0.2, 0.3, 0.4 and 0.5 mol% Nb⁵⁺ were represented as SP1, SP2, SP3 and SP4; Moreover, the SP3 ceramics of doping CaCO₃ with 4 mol% and 8 mol% were replaced by SP5 and SP6, respectively. The mixture was mixed by wet ball milling for 8 h in deionized water using an agate ball in a polyurethane jar, and they were dried at 115 ºC in drying oven, then the powders were calcined at 1190 ºC for 3 h in air. The mixture was ground again through ball-milling for 8 h. The dried powders were mixed with PVA and compacted by pressing at 150MPa to prepare the green compacts (φ15mm × 3mm size). The blocks were sintered in an aluminum tube at 1350 ºC for 2 h in air. Moreover, the surfaces of the fired BSTN ceramics were coated Ag-Zn alloy and then sintered at 540 ºC for 10 min in order to form electrodes, thereafter the room-temperature (RT) resistance of the specimens was measured using a digital multimeter, and the temperature dependence of resistance was measured in a temperature-programmable furnace at a heating rate of 1.6 ºC/min in the range of 25-300 ºC. In addition, the surface microstructure of the sintered ceramics was observed using scanning electron microscopy (SEM; S-3400N Hitachi, Japan). The average grain size of the ceramics was estimated by the line-intersection method.

The PALS were carried out at room temperature using a fast-fast coincidence ORTEC system with a time resolution of 240 ps (full width at half maximum, FWHM). A 3.7×10⁵ Bq source of ²²Na was sandwiched between two sheets of the samples ¹⁰10 Deng W, Huang YY, Wu DH, Cao MZ, Xiong LY. Effects of Cr and Sn on defects and electron densities in TiAl alloys. Materials Letters. 2002;56(4):593-596..

The CDBS were measured by sandwiching a 0.6 MBq ²²Na radioactive source, supported by two kapton films, between two pieces of the same sample. The CDBS were carried out by a two-detector coincidence system. A high purity Ge (HPGe) detector with a resolution of 1.3 keV at 511 KeV was determined to be the main detector. A NaI(Tl) scintillator was decided to the auxiliary detector supplying the coincidence signal, which was located in collinear geometry with the Ge detector for detecting the two 511 keV γ rays from the e⁺−e^- annihilation pair. A peak with about 10⁷ counts to background ratio of approximate 1.5 × 10⁴ on the high-energy side of the peak could be obtained in the peak of each spectrum. The CDBS of signal crystals of Si, and BSTN ceramics have been measured.

3. Results and Discussion

3.1. Microstructure of the ceramics

The microstructure of the BSTN ceramics with doping CaCO₃ of different contents sintered at 1350 ºC for 2 h in air is shown in Fig. 1. A slight difference in the grain size is observed. The average grain sizes of the samples doped Ca²⁺ of 0-8 mol% are 6.88 µm, 4.47 µm, and 2.80 µm, respectively. It indicates that the grain size of the specimens decreases quickly with an increase of the concentration of CaCO₃; Moreover, the grain size of the SP6 samples becomes very uniform in Fig. 1 (c), probably due to the inhibition of the grain growth with an increase in the CaCO₃ content. Thus, the particle-size distribution may be due to differences in the rates of grain growth.

Figure 1
The SEM micrograph on the surfaces of the BSTN ceramics doped CaCO₃ with different content; (a) 0 mol%, (b) 4 mol%, (c) 8 mol%.

3.2. XRD analysis

The XRD patterns of the BSTN ceramics prepared by firing at 1350 ºC for 2 h are shown in Fig. 2. The diffraction peaks of the samples exhibit a tetragonal structure in which the reflections (002) and (200) can be split into two peaks at room temperature. Moreover, the peak position where (111) is shifted to higher 2θ with the increase of Ca²⁺ may be due to the smaller interplanar distance, as calculated by the Bragg equation.

Figure 2
XRD patterns of BSTN ceramics doped CaCO₃ with various content; (a) 0 mol%, (b) 4 mol%, (c) 8 mol%.

3.3. Electrical properties and the resistivity jumping ratio of the BSTN ceramics

The dependence of the RT resistivity and the resistivity jumping ratio ( ρ_max/ρ_min) of the BSTN ceramics on the dopant content is shown in Table 1. From the table, the RT resistivity can be found to decrease firstly and then increase with an increase in the content of doping Nb⁵⁺ of 0.2−0.5 mol%; however, the trend of the resistivity jumping ratio as a function of the dopant concentration is contrary to that of the RT resistivity. The results show that the critical donor-dopant content is 0.4 mol% Nb⁵⁺. The corresponding RT resistivity and the resistivity jumping ratio is 714.3 Ω·cm and 2.77×10². The phenomenon signifies that the decrease in resistivity is due to the electron compensation of the substitution of Ti⁴⁺ by Nb^{5+ (}¹³13 Chan HM, Harmer MR, Smyth DML. Compensating Defects in Highly Donor-Doped BaTiO3. Journal of the American Ceramic Society.1986;69(6):507-510.^,¹⁴14 Pu Y, Wu H, Wei J, Wang B. Influence of doping Nb5+ and Mn2+ on the PTCR effects of Ba0.92Ca0.05(Bi0.5Na0.5)0.33TiO3 ceramics. Journal of Materials Science: Materials in Electronics. 2011;22(9):1479.. However, the increase in resistivity is generally attributed to the ionic compensation resulting from the formation of cation vacancies ¹⁵15 Brzozowski E, Castro MS, Foschini CR, Stojanovic B. Secondary phases in Nb-doped BaTiO3 ceramics. Ceramics International. 2002;28(7):773-777.

16 Nowotny J, Rekas M. Defect structure, electrical properties and transport in Barium Titanate. VII. Chemical diffusion in Nb-doped BaTiO3. Ceramics International. 1994;20(4):265-275.^-¹⁷17 Brzozowski E, Castro MS. Influence of Nb5+ and Sb3+ dopants on the defect profile, PTCR effect and GBBL characteristics of BaTiO3 ceramics. Journal of the European Ceramic Society. 2004;24(8):2499-2507.. In addition, we can see that the higher the doping Ca²⁺ content, the higher is the RT resistivity as well. This is because the doping CaCO₃ may be beneficial to the grain refinement in BSTN ceramics. But the resistivity jumping ratios of the SP5 and SP6 samples are far lower than that of the SP3. Furthermore, the temperature coefficient of resistance (α_T) of the BSTN samples is nearly affected by the dopant content in Table 1.

Thumbnail

Table 1
The electrical properties and the resistivity jumping ratio of the BSTN samples

3.4. Parameters of PALS of the BSTN ceramics

The defects in the BSTN samples can be characterized by the PALS. The spectra of the ceramics are analyzed by three decay lifetime (τ₁, τ₂ and τ₃) and the corresponding intensities (I'₁, I'₂ and I'₃)¹⁸18 Kirkegaard P, Eldrup M. Positronfit extended: A new version of a program for analysing position lifetime spectra. Computer Physics Communications. 1994;7(7):401-409. after background subtractions and source corrections. The τ₃ in each sample has long decay lifetime (> 1844 ps) and a small intensity (< 1%). This is because that the positrons are annihilated at the surface of samples, so it can be not considered in our experiment. Thus, the total intensities of I'₁ and I'₂ must be re-normalized and be labeled as I₁ and I₂, respectively. The τ₂ is the annihilated lifetime of the positron at the defect, its corresponding annihilated rate λ_d = τ₂^-1. On the base of the standard two-state trapping model ¹⁹19 Brandt W, Paulin R. Positron Diffusion in Solids. Physical Review B. 1972;5(7):2430., the positron annihilated rate λ_b and lifetime τ_b in the bulk are calculated for the following formula, λ_b = I₁τ₁^-1 + I₂τ₂^-1 and τ_b = λ_b^-1, respectively. While the average lifetime τ is based on the following equation, τ = I₁τ₁ + I₂τ₂. Finally, the electron densities in defects and bulk, n_d and n_b, can be be expressed as the following formula ²⁰20 Brandt W, Reinheimer J. Theory of Semiconductor Response to Charged Particles. Physical Review B. 1970;2(8):3104.: n = (τ-2) / 134, respectively. The characteristic parameters of the positron annihilate lifetime of the BSTN ceramics are shown in Table 2. Moreover, Fig. 3 shows that the dependent of the τ and n_b of the ceramics in Table 2 on the Nb⁵⁺-doped content.

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Table 2
The parameters of the positron annihilation lifetime spectra of the BTSN ceramics.

Figure 3
The average lifetime τ of the positrons and the free electron density n_b in the BSTN samples is as a function of the Nb₂O₅ content.

The mean positron annihilate lifetime τ increases firstly and then decreases with the increasing of the donor-doped concentration; however, the change trend of the electron densities in bulk n_b is just contrary to that of the τ in Fig. 3. Furthermore, it is found that the τ (206.46 ps) of the SP2 samples is minimum, this is because that the n_b (2.26 × 10^-2 a.u.) in the SP2 bulk is maximum at the same time. In addition, the electronic configuration of Nb and Ti are 4d⁴ 5s¹ and 3d² 4s², respectively. The d electron of Nb is more than that of Ti. Moreover, the electronic energy level of Nb (4d) is also higher than that of the Ti (3d). The conductivity characteristics are considered by electron compensation when the Ti in the BSTN ceramics (0.2 mol% < x < 0.3 mol%) is substituted by Nb. The results have been proved by the experimental data of the τ. But an increase in the τ is attributed to the vacancies compensation mechanism.

3.5. CDBS analysis of the BSTN samples

The background of the Doppler broadening spectrum can be reduced by the coincidence technique. In view of the constituent of the longitudinal horizontal momentum P_L of the annihilation e⁺−e^- pair the 511 keV site is broadened into (511 + ∆Ε) keV site. Moreover, the P_L is given by the expression: P_L = 2 ∆Ε / c, where ∆Ε is the frequency shift, and c is the velocity of light. In order to convenient for identifying various spectral lines, the ratio curves can be obtained by the comparison of every spectral line and the standard spectrum of Si.

The ratio curves for the SP1−SP6 samples with doping different dopant which are sintered at 1350 ºC in air is shown as in Fig. 4. The constituent of the longitudinal momentum P_L of the annihilation e⁺−e^- pair in 10^-3 m₀c is regarded as X-axis. The detailed shape of the high-momentum part of the Doppler spectrum is determined by the different effects from the positron annihilation with the electrons of each shell of the atom.

Figure 4
The ratio curves for the samples; (a) Nb and Ti ratio curves; (b) The SP1, SP2, SP3 and SP4 ratio curves, (c) The SP3, SP5 and SP6 ratio curves; The reference sample is Si.

It is showed that the main peak of the ratio curves of the BSTN samples cooled at 1100 ºC for 2 h after firing at 1350 ºC for 2 h in air increases at first and then decreases with the increasing of the donor-doped content in the Fig. 4. The Nb and Ti ratio curves show a peak at about 10.85 × 10⁻³ m₀c in Fig. 3(a); the intensities of the pecks are 4.28 and 2.79, respectively. These peaks are due to the positron annihilation with d electrons ⁸8 Deng W, Guo JT, Brusa RS, Karwasz GP, Zecca A. Effects of Zr and Nb on d electrons in NiAl alloy studied by coincidence positron annihilation spectroscopy. Materials Letters. 2005;59(27):3389-3392.^,²¹21 Ghosh VJ, Alatalo M, Asoka-Kumar P, Nielsen B, Lynn KG, Kruseman AC, et al. Calculation of the Doppler broadening of the electron-positron annihilation radiation in defect-free bulk materials. Physical Review B. 2000;61(15):10092.. Furthermore, the peaks of each BSTN samples lie between 2.79−4.28. The increase in the peak is because that the Ti is substituted by Nb. It is indicated that the annihilation of the e⁺-e^- pair is related to the donor-doped concentration. The intensities of the peck near 11.84 × 10^-3 m₀c for the SP3 specimens are more than that of the other samples; Moreover, the intensities of the maximum peak of the ceramics is 4.07. The formation of the peck at about 11.84 × 10^-3 m₀c is generally attributed to the annihilation of positrons and 2p electrons of oxygen atoms. It is inferred that the difference of the peak position of the samples with doping the same dopant is due to the annihilation of positron and 3d electrons of the cations, which can be obtained by the formation of the defect in the BSTN ceramics. Especially, lots of the titanium vacancies in the BSTN samples can be formed. Moreover, the bigger the content of the cation vacancies, the higher is the peak of the annihilation of positron with 3d electrons.

4. Conclusions

The influence of the Nb⁵⁺-doped content and the CaCO₃ on the electrical properties and the microdeffect of the BSTN ceramics were investigated by PALS and DSMB Techniques, which were fired at 1350 ºC for 2 h in air. The results indicated that the donor-doped content affected the formation of the microdefects and the electrical properties of the BSTN specimens. Moreover, both the RT resistivity and the positron annihibition lifetime τ of the BSTN ceramics decreased firstly and then increased with the increasing of the Nb⁵⁺-doped content. The critical donor-doped content is 0.4 mol%, which corresponding average positrons annihilate lifetime τ is 208.68 ps. meanwhile, It is found that the major peak of the ratio curves of the SP3 sample is lie in about 11.84 × 10^-3 m₀c.

5. Acknowledgements

This work was financially supported by the National Natural Science Foundation of China (No. 51402258), the Natural Science Foundation of Guangdong Province (No. 2015A030313706), the Science and Technology Planning Project of Guangdong Province (No. 2014A010105056), the Characteristic Creative Project in University of Guangdong Province (No. 2016KTSCX152), the Science and Technology Planning Project of Zhaoqing City (No. 201804030402).

References

¹
Mancini MW, Paulin Filho PI. Direct observation of potential barriers in semiconducting barium titanate by electric force microscopy. Journal of Applied Physics. 2006;100(10):104501.
²
Illingsworth J, Al-Allak HM, Brinkman AW, Woods J. The influence of Mn on the grain-boundary potential barrier characteristics of donor-doped BaTiO₃ ceramics. Journal of Applied Physics. 1990;67(4):2088-2092.
³
Heywang W. Resistivity Anomaly in Doped Barium Titanate. Journal of the American Ceramic Society. 1964;47(10):484-490.
⁴
Heywang W. Bariumtitanat als sperrschichthalbleiter. Solid-State Electronics. 1961;3(1):51-58.
⁵
Jonker GH. Some aspects of semiconducting barium titanate. Solid-State Electronics. 1964;7(12):895-903.
⁶
Pikart P, Hugenschmidt C, Horisberger M, Matsukawa Y, Hatakeyama M, Toyama T, et al. Positron annihilation in Cr, Cu, and Au layers embedded in Al and quantum confinement of positrons in Au clusters. Physical Review B. 2011;84(1):014106.
⁷
Wang D, Chen ZQ, Wang DD, Qi N, Gong J, Cao CY, et al. Positron annihilation study of the interfacial defects in ZnO nanocrystals: Correlation with ferromagnetism. Journal of Applied Physics. 2010;107(2):023524.
⁸
Deng W, Guo JT, Brusa RS, Karwasz GP, Zecca A. Effects of Zr and Nb on d electrons in NiAl alloy studied by coincidence positron annihilation spectroscopy. Materials Letters. 2005;59(27):3389-3392.
⁹
Tang Y, Zhang Y, Du PY, Deng W. Direct Control of Defects on Positron Lifetimes and Dielectric Constant of Microwave Ceramics. Journal of the American Ceramic Society. 2013;96(8):2537-2543.
¹⁰
Deng W, Huang YY, Wu DH, Cao MZ, Xiong LY. Effects of Cr and Sn on defects and electron densities in TiAl alloys. Materials Letters. 2002;56(4):593-596.
¹¹
Brzozowski E, Castro MS. Grain growth control in Nb-doped BaTiO₃ Journal of Materials Processing Technology. 2005;168(3):464-470.
¹²
Langhammer HT, Makovec D, Pu Y, Abicht HP, Drofenik M. Grain boundary reoxidation of donor-doped barium titanate ceramics. Journal of the European Ceramic Society. 2006;26(14):2899-2907.
¹³
Chan HM, Harmer MR, Smyth DML. Compensating Defects in Highly Donor-Doped BaTiO₃ Journal of the American Ceramic Society.1986;69(6):507-510.
¹⁴
Pu Y, Wu H, Wei J, Wang B. Influence of doping Nb⁵⁺ and Mn²⁺ on the PTCR effects of Ba_0.92Ca_0.05(Bi_0.5Na_0.5)0.33TiO₃ ceramics. Journal of Materials Science: Materials in Electronics. 2011;22(9):1479.
¹⁵
Brzozowski E, Castro MS, Foschini CR, Stojanovic B. Secondary phases in Nb-doped BaTiO₃ ceramics. Ceramics International. 2002;28(7):773-777.
¹⁶
Nowotny J, Rekas M. Defect structure, electrical properties and transport in Barium Titanate. VII. Chemical diffusion in Nb-doped BaTiO₃ Ceramics International. 1994;20(4):265-275.
¹⁷
Brzozowski E, Castro MS. Influence of Nb⁵⁺ and Sb³⁺ dopants on the defect profile, PTCR effect and GBBL characteristics of BaTiO₃ ceramics. Journal of the European Ceramic Society. 2004;24(8):2499-2507.
¹⁸
Kirkegaard P, Eldrup M. Positronfit extended: A new version of a program for analysing position lifetime spectra. Computer Physics Communications. 1994;7(7):401-409.
¹⁹
Brandt W, Paulin R. Positron Diffusion in Solids. Physical Review B. 1972;5(7):2430.
²⁰
Brandt W, Reinheimer J. Theory of Semiconductor Response to Charged Particles. Physical Review B. 1970;2(8):3104.
²¹
Ghosh VJ, Alatalo M, Asoka-Kumar P, Nielsen B, Lynn KG, Kruseman AC, et al. Calculation of the Doppler broadening of the electron-positron annihilation radiation in defect-free bulk materials. Physical Review B. 2000;61(15):10092.

Publication Dates

Publication in this collection
23 Sept 2019
Date of issue
2019

History

Received
23 Dec 2018
Reviewed
02 Apr 2019
Accepted
30 Apr 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Mancini MW, Paulin Filho PI. Direct observation of potential barriers in semiconducting barium titanate by electric force microscopy. Journal of Applied Physics. 2006;100(10):104501.

[2] ²
Illingsworth J, Al-Allak HM, Brinkman AW, Woods J. The influence of Mn on the grain-boundary potential barrier characteristics of donor-doped BaTiO₃ ceramics. Journal of Applied Physics. 1990;67(4):2088-2092.

[3] ³
Heywang W. Resistivity Anomaly in Doped Barium Titanate. Journal of the American Ceramic Society. 1964;47(10):484-490.

[4] ⁴
Heywang W. Bariumtitanat als sperrschichthalbleiter. Solid-State Electronics. 1961;3(1):51-58.

[5] ⁵
Jonker GH. Some aspects of semiconducting barium titanate. Solid-State Electronics. 1964;7(12):895-903.

[6] ⁶
Pikart P, Hugenschmidt C, Horisberger M, Matsukawa Y, Hatakeyama M, Toyama T, et al. Positron annihilation in Cr, Cu, and Au layers embedded in Al and quantum confinement of positrons in Au clusters. Physical Review B. 2011;84(1):014106.

[7] ⁷
Wang D, Chen ZQ, Wang DD, Qi N, Gong J, Cao CY, et al. Positron annihilation study of the interfacial defects in ZnO nanocrystals: Correlation with ferromagnetism. Journal of Applied Physics. 2010;107(2):023524.

[8] ⁸
Deng W, Guo JT, Brusa RS, Karwasz GP, Zecca A. Effects of Zr and Nb on d electrons in NiAl alloy studied by coincidence positron annihilation spectroscopy. Materials Letters. 2005;59(27):3389-3392.

[9] ⁹
Tang Y, Zhang Y, Du PY, Deng W. Direct Control of Defects on Positron Lifetimes and Dielectric Constant of Microwave Ceramics. Journal of the American Ceramic Society. 2013;96(8):2537-2543.

[10] ¹⁰
Deng W, Huang YY, Wu DH, Cao MZ, Xiong LY. Effects of Cr and Sn on defects and electron densities in TiAl alloys. Materials Letters. 2002;56(4):593-596.

[11] ¹¹
Brzozowski E, Castro MS. Grain growth control in Nb-doped BaTiO₃ Journal of Materials Processing Technology. 2005;168(3):464-470.

[12] ¹²
Langhammer HT, Makovec D, Pu Y, Abicht HP, Drofenik M. Grain boundary reoxidation of donor-doped barium titanate ceramics. Journal of the European Ceramic Society. 2006;26(14):2899-2907.

[13] ¹³
Chan HM, Harmer MR, Smyth DML. Compensating Defects in Highly Donor-Doped BaTiO₃ Journal of the American Ceramic Society.1986;69(6):507-510.

[14] ¹⁴
Pu Y, Wu H, Wei J, Wang B. Influence of doping Nb⁵⁺ and Mn²⁺ on the PTCR effects of Ba_0.92Ca_0.05(Bi_0.5Na_0.5)0.33TiO₃ ceramics. Journal of Materials Science: Materials in Electronics. 2011;22(9):1479.

[15] ¹⁵
Brzozowski E, Castro MS, Foschini CR, Stojanovic B. Secondary phases in Nb-doped BaTiO₃ ceramics. Ceramics International. 2002;28(7):773-777.

[16] ¹⁶
Nowotny J, Rekas M. Defect structure, electrical properties and transport in Barium Titanate. VII. Chemical diffusion in Nb-doped BaTiO₃ Ceramics International. 1994;20(4):265-275.

[17] ¹⁷
Brzozowski E, Castro MS. Influence of Nb⁵⁺ and Sb³⁺ dopants on the defect profile, PTCR effect and GBBL characteristics of BaTiO₃ ceramics. Journal of the European Ceramic Society. 2004;24(8):2499-2507.

[18] ¹⁸
Kirkegaard P, Eldrup M. Positronfit extended: A new version of a program for analysing position lifetime spectra. Computer Physics Communications. 1994;7(7):401-409.

[19] ¹⁹
Brandt W, Paulin R. Positron Diffusion in Solids. Physical Review B. 1972;5(7):2430.

[20] ²⁰
Brandt W, Reinheimer J. Theory of Semiconductor Response to Charged Particles. Physical Review B. 1970;2(8):3104.

[21] ²¹
Ghosh VJ, Alatalo M, Asoka-Kumar P, Nielsen B, Lynn KG, Kruseman AC, et al. Calculation of the Doppler broadening of the electron-positron annihilation radiation in defect-free bulk materials. Physical Review B. 2000;61(15):10092.

Sample	Nb⁵⁺/ mol%	CaCO₃/mol%	ρ₂₅/Ω·cm	α_T/%·ºC^-1	ρ_max/ρ_min
SP1	0.2	0	1754.4	3.1	131.8
SP2	0.3	0	911.1	3.1	130.9
SP3	0.4	0	714.3	4.8	276.7
SP4	0.5	0	1815.6	3.4	128.6
SP5	0.4	4	14263.8	4.1	27.0
SP6	0.4	8	18232.7	4.5	47.2

Sample	τ₁ / ps	τ₂ / ps	I₁ / %	I₂ / %	λ_b / ns^-1	λ_d / ns^-1	n_b / ×10-2a.u.	n_d / ×10^-2a.u.	τ / ps
SP1	193±3	393±34	92.5	7.5	4.98	2.54	2.23	0.41	208.00
SP2	192±2	429±48	93.9	6.1	5.03	2.33	2.26	0.25	206.46
SP3	193±2	402±47	92.5	7.5	4.98	2.49	2.22	0.36	208.68
SP4	199±3	478±67	94.7	5.3	4.87	2.09	2.14	0.07	213.79

Brasil

Brasil

Investigation on Electrical Properties and Microdefects of Nb⁵⁺-Doped BaTiO₃ Based Ceramics by Positron Annihilation Techniques

Abstract

1. Introduction

2. Experimental Procedures

3. Results and Discussion

3.1. Microstructure of the ceramics

3.2. XRD analysis

3.3. Electrical properties and the resistivity jumping ratio of the BSTN ceramics

3.4. Parameters of PALS of the BSTN ceramics

3.5. CDBS analysis of the BSTN samples

4. Conclusions

5. Acknowledgements

References

Publication Dates

History

Brasil

Brasil

Investigation on Electrical Properties and Microdefects of Nb5+-Doped BaTiO3 Based Ceramics by Positron Annihilation Techniques

Abstract

1. Introduction

2. Experimental Procedures

3. Results and Discussion

3.1. Microstructure of the ceramics

3.2. XRD analysis

3.3. Electrical properties and the resistivity jumping ratio of the BSTN ceramics

3.4. Parameters of PALS of the BSTN ceramics

3.5. CDBS analysis of the BSTN samples

4. Conclusions

5. Acknowledgements

References

Publication Dates

History

Investigation on Electrical Properties and Microdefects of Nb⁵⁺-Doped BaTiO₃ Based Ceramics by Positron Annihilation Techniques