1. Introduction
Dielectric capacitors have been widely used as energy-storage components in various electronic and electrical applications [1,2], with more focus in high-power and pulse-power applications, because of their higher power density, faster charge–discharge rate, and robustness when compared with fuel cells and batteries [3]. However, the energy density of dielectric capacitors is usually lower than other energy storage devices, which limits their applications. In addition, modern dielectric capacitors are challenged by operating under high-temperature environments, for example, the power inverters used for hybrid vehicles are operated at temperatures over 140 °C [4] and the devices for exploring underground oil or gas are required to withstand temperature over 200 °C [5]. The low glass transition point of present commercial polymer capacitors limit their applications at elevated temperature [6]. In contrast, ceramic capacitors benefit from their inorganic structure, and so are more capable for hard environments. However, the energy efficiency of ceramic capacitors usually reduces as the operating temperature increases due to the leakage current and/or space charge effect [2]. The reduced energy efficiency at elevated temperature corresponds to severe energy dissipation in the form of heat, raising the concerns of device stability and reliability. Therefore, a demand exists for exploration of high temperature dielectric ceramics with good energy storage properties.
The energy density and efficiency of capacitors can be calculated by the following the Equations:
(1)
(2)
(3)
where W and Wrec represent the stored energy density and recoverable energy density. The energy efficiency (η) is defined by the ratio between Wrec and W. It can be seen that high maximum polarization (Pmax), low remnant polarization (Pr), and high breakdown strength (BDS) relating to the various electric field will greatly benefit the recoverable energy density and energy efficiency. However, the Pmax or Pr for many dielectric materials are strongly temperature-dependent [7], leading to inferior stability of the dielectric capacitors. In addition, at elevated temperature, the trapped charges existing in the ceramics gain enough energy and contribute to the conductivity, resulting in an increased leakage current and decreased energy efficiency, which will accelerate thermal breakdown of the ceramics by generating more heat [8,9]. The opposite way, the capacitors with high energy efficiency could operate at elevated temperature without additional cooling devices, which reduces the volume and cost of the whole system. Many lead-containing materials attracted wide attention as energy storage capacitors in last few decades due to their excellent properties, such as PbZrO3 and (Pb,La)(Zr,Ti)O3 (PLZT)-based systems [10,11]. However, considering the environmental and health concerns of the lead component, lead-free dielectrics have been the mainstay in research over the last 20 years.Strontium titanate (SrTiO3, ST) has been extensively studied for energy storage applications in the past few years due to its high permittivity (~300), low dielectric loss (<1%) and relatively high BDS (~200 kV/cm) [12]. Many efforts have been attempted for improving the energy storage properties of ST, such as modification with the Bi3+ cation, Ca2+ cation or rare earth cations for increasing permittivity [13,14,15], meanwhile enhancing the BDS [12]. Of particular importance is that the bismuth-containing relaxor ferroelectrics have attracted increasing attention as promising alternatives for lead-free relaxors, due to the fact that the Bi3+ ions possess the lone-pair electronic configuration 6s2 being analogous to Pb2+ ions, which can be hybridized with O 2p orbitals, resulting the high saturation polarization. It was reported that bismuth-modified strontium titanate ((Sr0.7Bi0.2)TiO3 abbreviated to SBT) dielectric material exhibited strong relaxor-like behavior, showing smeared phase transition temperature and high polarization [14], while the energy storage density of 1.63 J/cm3 at 217.6 kV/cm was reported for relaxor ceramic (Sr0.85Bi0.1)TiO3 [16]. In addition, SBT has been selected as an endmember to form solid solutions with other compounds to improve the dielectric and energy storage properties. It was reported that a 0.55(Na0.5Bi0.5)TiO3–0.45SBT multilayer ceramic capacitor showed a high energy density of 9.5 J/cm3 and energy efficiency of 92% at 720 kV/cm [17]. Although the maximum energy density of 48.5 J/cm3 was obtained in 0.9SBT–0.1BiFeO3 thin-film capacitor, the energy efficiency was relatively low (48%) [18].
Based on the unique relaxor characteristic of Bi-based compound, in order to improve the temperature stability and energy storage density, numerous Bi(Me′Me″)O3 (Me′ = Mg2+, Zn2+; Me″ = Ti4+, Nb5+, et al.) endmembers have been attempted for dielectric solid solutions. For example, BaTiO3–Bi(Me′Me″)O3 ceramics transfer from typical ferroelectric to relaxor with increasing Bi(Me′Me″)O3 concentration, showing improved temperature stability, low dielectric loss, as well as improved energy efficiency [9,19,20,21,22,23]. Among these solid solutions, 0.7BaTiO3–0.3Bi(Mg0.5Zr0.5)O3 was found to exhibit high stability over a wide temperature range from −20 °C to 430 °C with low permittivity variation (< ±15%) and relatively low loss (~2%) [24]. Therefore, in this work, Bi(Mg0.5Zr0.5)O3-modified SBT relaxor ferroelectric solid solution (1-x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ((1-x)SBT-xBMZ) was fabricated, and its energy storage properties were studied in detail. A high energy storage density of 4.2 J/cm3 at applied electric field of 380 kV/cm was obtained for the x = 0.06 sample. The energy efficiency at 200 kV/cm was maintained above 90% over the temperature range of 25 °C to 125 °C, exhibiting an excellent temperature stability.
2. Materials and Methods
(1-x)SBT-xBMZ ceramics with x = 4%, 6%, 8%, 10%, 15% (abbreviated as 4BMZ, 6BMZ, 8BMZ, 10BMZ, and 15BMZ, respectively) were fabricated by a conventional high-temperature solid state reaction method using reagent powders SrCO3 (99.9%, Alfa Aesar, Haverhill, MA, USA), TiO2 (99.0%, Strem Chemicals, Newburyport, MA, USA), Bi2O3 (99.9%, Alfa Aesar), MgO (99.0%, Alfa Aesar), and ZrO2 (99.7%, Alfa Aesar). These powders were baked at 150 °C for 12 h to remove the absorbed moisture and then stoichiometrically weighed with the addition of 1–2% excess MgO [25]. The mixed powders were ball milled for 12 h with ethanol as medium. Thereafter, the powders were re-milled again after calcination at 900 °C for 2 h. The median particle size of re-milled powers were around 0.5–0.7 μm. Then 0.2 wt % Rhoplex binder was added to the slurry of each composition and the mixtures were ball-milled for 2 h. The slurries with binder were dried, granulated, and sieved. Then the dried powders were pressed into 15-mm-diameter pellets. In order to increase the green density, these pellets were pressed under an isostatic pressure of 200 MPa for 10 min after burning out the binder at 600 °C. The pellets were sintered at 1200–1250 °C for 2 h with self-source powder in a closed crucible. For dielectric and electrical measurements, the silver electrodes and gold electrodes were prepared on polished parallel sample surfaces, respectively. In addition, the pellets were polished to ~100 μm for P-E and breakdown strength measurements. The X-ray diffraction patterns were recorded on a diffractometer (GBC MMA XRD) using Cu Kα radiation with the ground pellets. The microstructure information of polished and thermally etched surfaces were collected using scanning electron microscopy (SEM) (JSM-7500FA, JEOL, Akishima Tokyo). Grain size distributions were calculated using Nano Measurer by measuring the selected area of SEM images. In order to measure the dielectric properties of the studied samples, silver electrodes were fired on both sides of polished samples. The dielectric data was collected on a LCR meter (4980AL, Keysight, Santa Rosa, CA, USA) from 100 Hz to 1 MHz over temperature range of −100 °C to 400 °C. For the electrical measurements, various electric fields were applied to the sample at 10 Hz and room temperature using a ferroelectric tester (TF2000, aixACCT, Aachen, Germany) to obtain P-E hysteresis loops. Thermal stability and fatigue endurance were measured at 200 kV/cm from 25–150 °C and 1 to 105 cycles, respectively. The charge–discharge rate was measured with charge–discharge system (PK-CRP1701, PolyK, State College, PA, USA) based on the resistance–capacitance circuit with 2 kΩ load resistance.
3. Results and Discussion
3.1. Phase Structure and Microstructure Characterization
The XRD patterns of (1−x)SBT-xBMZ ceramics with x = 4–15% are shown in Figure 1a. It can be seen that all samples exhibit pseudocubic perovskite structure, as evidenced by the single (111) and (200) peaks. Figure 1b shows the enlarged (200) peaks shifting to a lower angle with increasing BMZ concentration, corresponding to the expansion of unit cell volume. It can be attributed to the larger effective ionic radius (r) of (Mg0.5Zr0.5)3+ (r (Mg0.5Zr0.5)3+ = 0.72 Å calculated from the average ionic radii of Mg2+ and Zr4+) than that of Ti4+ (r(Ti4+) = 0.605 Å) on the B-site. The lattice parameters are obtained from XRD patterns, the linearly increasing trend with BMZ concentration from x = 4% to 15% can be seen in Figure 1c. An additional peak around 30° corresponding to the secondary phase Bi2Ti2O7 was observed for BMZ in the range of 6–8%, above which, the secondary phase was changed to Sr2Bi4Ti5O18 [25]. The densities of SBT-BMZ samples are above 95% theoretical, being 5.46 g/cm3 for x = 0.04, slightly increasing to 5.68 g/cm3 for x = 0.15.
The SEM images of studied ceramics with thermally etched surface are shown in Figure 2. All (1−x)SBT-xBMZ ceramics not only show minimal porosity but also have fine grains with average grain size smaller than 1 μm, as shown in Figure 2i,j. The dense microstructure with fine grains are expected to benefit the enhancement of BDS [26].
3.2. Dielectric and Energy-Storage Characterizations for (1−x)SBT-xBMZ Ceramics
The dielectric properties of BT-Bi(Me′Me”)O3-based ceramics have been widely investigated to acquire deeper understanding, including the relationship of relative dielectric permittivity (εr) and the component Bi(Me′Me”)O3 endmember. Several previous studies show that the phase transition peaks became broader and smeared with increasing Bi(Me′Me”)O3 substitutions in BT-Bi(Me′Me”)O3 solid solutions, leading to the enhancement of thermal stability [23,24,27,28]. Figure 3a–e shows the temperature dependence of dielectric permittivity (εr) and loss (tanδ) for (1−x)SBT-xBMZ ceramics. The smeared phase transition and frequency dispersion behavior of permittivity and dielectric loss are observed near the dielectric maximum temperature (Tm), exhibiting a typical relaxor behavior. Generally, the diffuseness of phase transition can be evaluated by modified Curie–Weiss law 1/ε − 1/εm = (T − Tm)γ/C, where εm and Tm represent maximum permittivity and the corresponding temperature, respectively. The value γ = 2 represents a complete diffuse phase transition while γ = 1 represents a classical ferroelectric transition [29]. In order to reduce the effects of space charge, the γ values for (1-x)SBT-xBMZ ceramics are calculated using permittivity data at 1 MHz. Figure 3f gives the γ values of (1-x)SBT-xBMZ ceramics, being above 1.5, indicating relaxor characteristics. With increasing BMZ, the maximum permittivity (εm) at 1 kHz for ceramics with x up to 10% are similar, but the Tm increases gradually from −68 °C to −27 °C, higher than the Tm of (Sr0.7Bi0.2)TiO3 ceramics which is around −100 °C [30]. The lower permittivity and higher dielectric loss for samples with x = 15% may be related to the secondary phase. Of particular interest is that the dielectric loss is less than 3% for all the studied ceramics over a wide temperature range, as shown in Table 1, exhibiting the potential of high energy efficiency in the same temperature range. In addition, dielectric loss corresponds the reliability of capacitors, lower generated heat leading to the associated low possibility of thermal breakdown. It should be noted that an additional dielectric peak around 290 °C was observed for 10BMZ and 15BMZ, as shown in Figure 3d,e. This observation can be explained by the secondary phases (Sr2Bi4Ti4O15) which was reported to possess a Curie temperature around 285 °C [31].
The P–E loops at 200 kV/cm for (1−x)SBT-xBMZ ceramics with different BMZ content are compared and shown in Figure 4a. It is clear to see that the 4BMZ and 6BMZ ceramics exhibit slim P–E loops at 200 kV/cm, indicating high energy efficiencies above 92%. With increasing BMZ concentration, Pmax increases first then decreases, relevant to the dielectric permittivity, as listed in Table 1. The highest Pmax was found for 8BMZ, but its large Pr would reduce the recoverable energy density and decreases energy efficiency. The hysteresis increases obviously in 8BMZ, 10BMZ and 15BMZ samples, resulting in the decreased Wrec with increasing BMZ concentration, as shown in Figure 4b. The increased hysteresis may be related to the increased secondary phases. Based on the preliminary results, we chose the 6BMZ sample for further evaluation of the energy storage property.
3.3. Energy Storage Properties of 0.94SBT-0.06BMZ Ceramic
The unipolar P–E loops of 6BMZ ceramic are measured at 10 Hz with different applied electric fields as shown in Figure 5a. It is clear that all P–E loops are slim with negligible hysteresis which are associated with the small value of Pr, contributing to the high energy efficiency. Pr and Pmax as a function of electric field for 6BMZ ceramic are shown in Figure 5b. When the electric field increased from 50 to 380 kV/cm, the Pmax value enhances monotonically from 6.7 μC/cm2 to 30.3 μC/cm2, while the Pr remains at almost the same values. Thus, the ΔP (ΔP = Pmax − Pr) keeps increasing as function of applied field, which is beneficial for enlarging Wrec and η; the results are given in Figure 5c. The maximum Wrec of 4.2 J/cm3 was obtained at 380 kV/cm. On the other hand, the energy efficiency exhibits remarkable stability over the applied field up to 320 kV/cm with values larger than 90%, above which the η slightly drops to 88%.
High BDS is advantageous in dielectric materials for obtaining high W as shown in Equation (1). The Weibull distribution has been used as a capable analysis method to explore the breakdown strength of ceramics, as given in the following equations:
(4)
(5)
(6)
where i is the serial number of sample. Ei, Pi and n are the breakdown strength of each test sample, the probability of breakdown and the summation samples, respectively. The ascending sort of breakdown strength for samples is shown as . The Weibull modulus (m) can be obtained by the slope of the fitted linear line of Xi and Yi, which is one of the important parameters that represents the reliability of experimental data. The Weibull characteristic breakdown strength (Eb) can be calculated by the intercept between the fitted linear line and Yi = 0. As shown in Figure 5d, the m value for 6BMZ ceramic is 17, leading to a high level of confidence. The calculated Eb of 6BMZ is 460 kV/cm which is much higher than other lead-free energy storage ceramics [32,33,34,35,36], as shown in Table 2. The energy storage properties of BaTiO3-Bi(Me′Me″)O3 ceramics have been widely studied, and the obtained energy densities have been found to be around 1–3 J/cm3 in previous research as shown in Table 2. The dielectric maxima temperatures of most of the studied BaTiO3-Bi(Me′Me″)O3 ceramics are around or above room temperature, leading to a relatively high dielectric loss at room temperature. However, in this work, the Tm of 6BMZ is far below room temperature, resulting in a low dielectric loss at room temperature and above. The depressed tanδ is believed to be associated with high breakdown strength, and hence the high energy density as well as the high energy efficiency. The ultrahigh breakdown strength of 6BMZ ceramic leads to improved Wrec of 4.2 J/cm3, which is favorable for energy storage applications.For high-temperature energy-storage applications, thermal stability plays a key role when working at elevated temperatures. For example, the operating temperature can be higher than 140 °C in hybrid electric vehicles, thus requiring some electronic components to be protected by cooling systems [37]. Dielectric materials that work and maintain stability at high temperature could not only reduce the cost but also the volume of the whole energy storage system. The temperature-dependent unipolar P–E loops for 6BMZ ceramic at various temperatures from ambient to 150 °C at 200 kV/cm are shown in Figure 6a. It can be seen that all the P–E loops are slim, indicating the high temperature stability. The Pmax value was found to slightly decrease, which is related to the decreased permittivity at elevated temperature, while the Pr remains at a low value over a wide temperature range, indicating the 6BMZ ceramic capable of operating at high temperature. Figure 6b shows Wrec and η as functions of temperature, the decrease of Wrec is on the order of 14% due to reduced permittivity at elevated temperature. Of particular significance is that the variation of η is minimal up to 130 °C, associated with the low dielectric loss and temperature-insensitive Pr. The excellent thermal stability of η for 6BMZ ceramic make it very promising for energy storage applications working at elevated temperature.
3.4. Fatigue Endurance and Charge–Discharge Rate for 0.94SBT-0.06BMZ Ceramic
To further investigate the energy storage properties for 6BMZ ceramic, the fatigue cycling endurance and a charge-discharge rate experiment were performed. Strong fatigue endurance is essential for energy storage capacitors in practical applications. Figure 7a displays the unipolar P–E loops for 6BMZ ceramic at 200 kV/cm under different cycle numbers. The energy storage performances of the 6BMZ ceramic are reproducible after 105 cycles, where the unipolar P–E loops maintain the same shape over the cycling, small difference can be seen in the inset figure of Figure 7a. The variation of Wrec and η for fatigue cycling numbers are given in Figure 7b; here the Wrec value remains almost the same value while the η slightly drops from 95% to 92% after 105 cycles, demonstrating that 6BMZ sample possesses excellent cycling reliability.
The fast discharge rate is critical for pulse-power applications. The discharged energy density can be calculated by , where RL, i(t) and Vol represent the total load resistor (2 kΩ), the discharge current through RL, and the sample volume, respectively. The calculated Wdis at an applied electric field of 200 kV/cm as a function of time for 6BMZ ceramic is given in Figure 8. The discharge time τ0.9 is the time required to release 90% of total Wdis value. The τ0.9 for 6BMZ at room temperature is 0.62 μs, indicating the great potential of 6BMZ for pulse power capacitors.
4. Conclusions
In summary, lead-free (1−x)SBT-xBMZ ceramics were fabricated by conventional solid state processing. The highest recoverable energy density of 4.2 J/cm3 and high energy efficiency of 88% were obtained at applied electric field of 380 kV/cm for 0.94(Sr0.7Bi0.2)TiO3-0.06Bi(Mg0.5Zr0.5)O3 ceramic. The 6BMZ ceramic shows a good temperature stability over a wide temperature range from room temperature to 150 °C. In addition, the 6BMZ ceramic also exhibits excellent cycling stability over 105 charging–discharging cycles. Together with its fast discharge rate, the τ0.9 is on the order of 0.62 μs, demonstrating that the 0.94(Sr0.7Bi0.2)TiO3-0.06Bi(Mg0.5Zr0.5)O3 ceramic shows promising potential as a lead-free dielectric for high-temperature, high-power energy storage applications.
Author Contributions
Conceptualization, X.K. and S.Z.; validation, X.K. and S.Z.; formal analysis, X.K. and L.Y.; investigation, X.K. and L.Y.; resources, X.K.; data curation, X.K.; writing—original draft preparation, X.K.; writing—review and editing, X.K., L.Y., Z.C. and S.Z.; visualization, X.K.; supervision, S.Z. and Z.C. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Australian Research Council, grant number FT140100698.
Acknowledgments
The authors acknowledge the use of facilities within the UOW Electron Microscopy Centre. The authors also would like to thank Dr. Andrew Nattestad for preparing the electrodes.
Conflicts of Interest
The authors declare no conflict of interest.
Figures and Tables
Figure 1. (a) XRD patterns of (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics; (b) enlarged diffraction peaks from 46° to 47° of (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics; (c) the lattice parameters as a function of BMZ concentration.
Figure 2. SEM micrographs of the polished and thermally etched surfaces for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics: (a) x = 4%; (b) x = 6%; (c) x = 8%; (d) x = 10%; (e) x = 15%; The grain size of (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics: (f) x = 4%; (g) x = 6%; (h) x = 8%; (i) x = 10%; (j) x = 15%.
Figure 3. Temperature dependence of εr and tanδ of (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics: (a) x = 4%; (b) x = 6%; (c) x = 8%; (d) x = 10%; (e) x = 15%; (f) ln (1/ε − 1/εm) as a function of ln (T − Tm) for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics at 1 MHz.
Figure 3. Temperature dependence of εr and tanδ of (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics: (a) x = 4%; (b) x = 6%; (c) x = 8%; (d) x = 10%; (e) x = 15%; (f) ln (1/ε − 1/εm) as a function of ln (T − Tm) for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics at 1 MHz.
Figure 4. (a) The P–E loops at 200 kV/cm for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics; (b) the stored energy density (W), recoverable energy density (Wr), and energy efficiency (η) for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics as functions of different BMZ concentration at 200 kV/cm and ambient temperature.
Figure 5. (a) The unipolar P–E loops for 6BMZ ceramic; (b) the electric filed dependent Pmax, Pr, and ΔP for 6BMZ ceramic; (c) the calculated W, Wrec, and η versus applied electric field of 6BMZ ceramic; (d) Weibull distribution of the breakdown strength data.
Figure 6. (a) The unipolar P–E loops for 6BMZ ceramic at different temperature at 200 kV/cm; (b) Wr and η of 6BMZ ceramic as functions of temperature.
Figure 7. (a) Unipolar P–E loops for 6BMZ ceramic under different fatigue cycling number; (b) Wr and η as functions of charging–discharging cycles from 1 to 105 for 6BMZ ceramic.
Figure 8. Discharge energy density as a function of time for 6BMZ ceramic at 200 kV/cm and ambient temperature.
The summary of dielectric performance at 1 kHz and energy storage properties at 200 kV/cm for (1−x)(Sr0.7Bi0.2)TiO3-xBi(Mg0.5Zr0.5)O3 ceramics.
Sample | Tm (°C) | ε m | ε @ RT | tanδ @ RT | T-range (°C) tanδ < 3% | Wrec @ RT (J/cm3) | η @ RT (%) |
---|---|---|---|---|---|---|---|
4BMZ | −68 | 1020 | 865 | 0.06% | −80–400 | 1.50 | 92 |
6BMZ | −64 | 1020 | 880 | 0.06% | −75–380 | 1.71 | 92 |
8BMZ | −56 | 1110 | 990 | 0.08% | −70–390 | 1.59 | 75 |
10BMZ | −54 | 940 | 870 | 0.04% | −70–350 | 1.34 | 81 |
15BMZ | −27 | 890 | 865 | 0.2% | −40–340 | 1.22 | 77 |
Comparison of energy-storage properties between the 0.94SBT-0.06BMZ ceramic and other lead-free ceramics.
Composition | Wrec (J/cm3) | η (%) | Eapp (kV/cm) | Eb (kV/cm) | Ref. |
---|---|---|---|---|---|
0.85BaTiO3-0.15Bi(Zn2/3Nb1/3)O3 | 0.79 | 93.5 | 131 | 262 | [22] |
0.9BaTiO3-0.1Bi(Mg2/3Nb1/3)O3 | 1.13 | 95.8 | 143.5 | ~270 | [32] |
0.61BiFeO3-0.33BaTiO3-0.06Ba(Mg1/3Nb2/3)O3 | 1.56 | 75 | 125 | - | [33] |
0.88BaTiO3-0.12Bi(Mg1/2Ti1/2)O3 | 1.81 | ~88 | 224 | 535.5 | [20] |
0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3 | 2.032 | 88 | 270 | 340 | [9] |
0.85BaTiO3-0.15Bi(Zn0.5Sn0.5)O3 | 2.21 | 91.6 | 230 | 280 | [34] |
0.9BaTiO3-0.1Bi(Zn0.5Zr0.5)O3 | 2.46 | ~73 | 264 | 266.5 | [35] |
(Na0.25Bi0.25Sr0.5)(Ti0.8Sn0.2)O3 | 3.4 | 90 | 310 | 330 | [36] |
0.94(Sr0.7Bi0.2)TiO3-0.06Bi(Mg0.5Zr0.5)O3 | 4.2 | 88 | 380 | 460 | This work |
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Abstract
Due to the enhanced demand for numerous electrical energy storage applications, including applications at elevated temperatures, dielectric capacitors with optimized energy storage properties have attracted extensive attention. In this study, a series of lead-free strontium bismuth titanate based relaxor ferroelectric ceramics have been successfully synthesized by high temperature solid-state reaction. The ultrahigh recoverable energy storage density of 4.2 J/cm3 under 380 kV/cm, with the high efficiency of 88%, was obtained in the sample with x = 0.06. Of particular importance is that this ceramic composition exhibits excellent energy storage performance over a wide work temperature up to 150 °C, with strong fatigue endurance and fast discharge speed. All these merits demonstrate the studied ceramic system is a potential candidate for high-temperature capacitors as energy storage devices.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer