Corresponding author: Olga V. Malyshkina ( olga.malyshkina@mail.ru ) © 2020 Olga V. Malyshkina, Gregory S. Shishkov, Andrey A. Martyanov, Alexandra I. Ivanova.
This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Citation:
Malyshkina OV, Shishkov GS, Martyanov AA, Ivanova AI (2020) Effect of sintering temperature on dielectric properties of barium titanate ceramics and composite. Modern Electronic Materials 6(4): 141-146. https://doi.org/10.3897/j.moem.6.4.65576
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The structure and dielectric properties of barium titanate ceramics samples sintered at 1100, 1150, 1200, 1250 and 1350 °C have been compared with the dielectric properties of 80 vol.% barium titanate + 20 vol.% barium ferrite composite samples sintered at 1150, 1200 and 1250 °C. It has been shown that polarization sufficient for existence of the piezoelectric effect is only achieved in barium titanate samples sintered at 1250 and 1350 °C. Furthermore the pyroelectric coefficient and reversal polarization of these samples are far higher than those of samples sintered at lower temperatures. Analysis of the sample structures has confirmed that the dielectric properties of barium titanate ceramics depend on grain size and therefore on sintering temperature. Based on the experimental results we have selected the optimum sintering temperature for 80 vol.% barium titanate + 20 vol.% barium ferrite composite to be 1250 °С. Further increase in sintering temperature to 1300 °C showed that this composite has a eutectic. The temperature dependence of the permittivity of the barium titanate / barium ferrite composite sintered at 1250 °С is similar to that of BaTiO3 ceramics samples sintered at 1350 °С. The room temperature permittivity of the composite samples also proves to be far higher than that of barium titanate ceramics samples sintered at the same temperatures. Barium ferrite addition to barium titanate increases the permittivity of the composite and also diffuses the ferroelectric phase transition and shifts the permittivity maximum temperature by 10 °C towards higher temperatures.
piezoelectric ceramics, barium titanate, magnetoelectric composite, permittivity, Curie temperature, spontaneous polarization, pyroelectric effect, piezoelectric coefficient
The design of fundamentally new materials differing from currently used ones by composition and, more importantly, by functionality is critical for the development of intellectual technologies [
The basic material possessing ferroelectric and magnetic properties which is widely studied nowadays is bismuth ferrite [
In the meantime composite materials in which a bulk combination of ferroelectric and magnetic materials is implemented are more promising from practical viewpoint because controlling the composition of magnetoelectric composites allows one to design compositions with practically desirable dielectric and magnetic permeability figures. These composites are currently designed following two directions:
layered composites in which layers of ferroelectric and magnetic materials interchange [
polymer magnetic materials containing ferroelectric ceramics [
Research efforts have been started recently aimed at designing magnetoelectric composites containing magnetic and piezoelectric ceramics [
Barium titanate ceramics pertain to piezoelectric materials finding wide practical application. It is safe to assume that combining barium titanate with barium ferrite will produce a composite having electromagnetic properties. The authors have studied this composite [
The aim of this work is to production barium titanate ceramics and barium titanate / barium ferrite composite at different sintering temperatures, compare their dielectric properties and identify the optimum sintering temperatures.
We produced and studied samples of the barium titanate (BaTiO3) ceramics and a barium ferrite (BF) / barium titanate (BaTiO3) composite. BF and BaTiO3 ceramics were synthesized using standard technologies [
We studied the structure and dielectric properties of the BaTiO3 samples (temperature dependence of permittivity, dielectric hysteresis loop and presence of pyroelectric and piezoelectric effects).
The structure of the samples was examined under a JEOL 6510LV scanning electron microscope. The temperature dependence of the permittivity of the samples was tested on a special temperature equipment with heating rate control option. The equipment included a low-voltage furnace and a furnace control unit consisting of a programmable thermal controller (Miniterm) with a power amplifier and a computer with control software. The sample capacity was measured with a Е7-20 immitance meter. Spontaneous polarization measurements were carried out based on the experimental dielectric hysteresis loops using the Sawyer–Tower circuit, the pyroelectric coefficient was measured using a dynamic method [
The surface structure of the barium titanate ceramics samples was examined using scanning electron microscopy (SEM). The results showed that the shape and size of barium titanate grains depend strongly on sintering temperature (Fig.
We measured the grain sizes using a special option of the scanning electron microscope (scaler). Grain size was analyzed for the second type of grains in which recrystallization started. The dependence of average grain size r on sintering temperature is shown in Fig.
One can therefore conclude that reacrystallization during which grains coalesce and grow ends at 1250 °C following which the grain size increases only due to the grain growth. This is also confirmed by the appearance of growth steps in the samples sintered at 1250 °C and higher temperatures (Fig.
The temperature dependence of the permittivity of the BaTiO3 ceramics samples are shown in Fig.
To verify the existence of spontaneous polarization at a macroscopic level we studied the dielectric hysteresis loops for the samples in a 900 V/mm AC field. Based on the dielectric hysteresis loops we calculated the reversal polarization for BaTiO3 ceramics samples sintered at different temperatures. The calculation results are presented below.
Before measuring the pyroelectric and piezoelectric parameters we poled the samples in a 1500 V/mm DC electric field.
The square-modulated heat flow source for the pyroelectric measurements was a 960 nm IR laser. The pyroelectric current was measured in short circuit mode with an OR297 operational amplifier having a 2.5×108 V/A current to voltage conversion ratio. The pyroelectric coefficient calculation results are presented in Fig.
The resonance and antiresponance frequency measurements for piezoelectric coefficient study by a resonance method showed that piezoelectric resonance only exists in the samples sintered at 1250 and 1350 °C. The experimentally measured piezoelectric moduli d31 and d33 (Table
Different magnification SEM images of BaTiO3 sample structure for sintering temperatures of (a and b) 1100, (c and d) 1150, (e and f) 1200, (g and h) 1250 and (i and j) 1350 °C.
Temperature dependences of permittivity for (a) BaTiO3 and (b) BF20 – BaTiO3 80 samples sintered at (4) 1100, (1) 1150, (2) 1200, (3) 1250 and (5) 1350 °C.
Piezoelectric modules of BaTiO3 samples sintered at different temperatures.
Sintering temperature, °C | d 31, 10-12 C/N | d 33, 10-12 C/N |
---|---|---|
1250 | 32 | 191 |
1350 | 31 | 210 |
The studies of the dielectric properties for BaTiO3 ceramics showed that only the sample sintered at 1350 °C has the true ferroelectric properties. Although the sample sintered at 1250 °C had high piezoelectric moduli, its pyroelectric coefficient and spontaneous polarization were inferior to those of the sample sintered at 1350 °C. However the experiments for obtaining barium ferrite / barium titanate composite (BF – BaTiO3) revealed a eutectic in this mixture that renders impossible sample sintering at temperature 1300 °C. It was therefore of interest to compare the temperature dependence of the permittivity of the BaTiO3 ceramics samples with those of BF – BaTiO3 composite.
The data on the temperature dependence of the permittivity of the 20 % barium ferrite 80% + barium titanate composite samples sintered at 1150, 1200 and 1250 °C are shown in Fig.
Study of the effect of BaTiO3 ceramics sintering temperature showed that the ferroelectric properties of the samples are the better the higher the sintering temperature. This regularity shows itself in the value of the reversal polarization and pyroelectric response, presence or absence of piezoelectric effect in poled samples and value of the permittivity at the Curie temperature. The phase transition temperature does not depend on sintering temperature and the maximum permittivity of all the samples is observed at 130 °C. However the permittivity maximum values depend on sintering temperature: the higher the sintering temperature the higher the permittivity of the samples at the Curie temperature.
Although the BaTiO3 ceramics sample sintered at 1350 °C has the best ferroelectric properties, the pyroelectric and piezoelectric properties of the samples sintered at 1250 °C are but slightly inferior to it. This shows a theoretical possibility of reducing sintering temperature of barium titanate based composite to 1250 °C.
Indeed experiments showed that a sintering temperature of 1250 °C is below the eutectic one but on the other hand allows production BF – BaTiO3 composite samples with a permittivity temperature dependence similar to that of BaTiO3 ceramics samples sintered at 1350 °C. Barium ferrite addition to barium titanate ceramics increases the permittivity of the sample and diffuses the phase transition. The permittivity maximum temperature shifts by 10 °C towards higher temperatures.
The work was performed on the equipment of the Center for Collective Use of the Tver State University.