Ferroelectric and electromechanical performance of diverse engineered states of Mn-doped 0.75Pb(Mg1/3Nb2/3)O3-0.25PbTiO3 ceramics

“…It can be seen that all the transparent ceramics have saturated ferroelectric hysteresis and butterfly-shaped electric-field-induced strain curves, showing representative ferroelectric and piezoelectric performance. In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. , Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. , Figure e shows the variation of the coercive field ( E c ) and remanent polarization ( P r ) of PIN-PMN-PT transparent ceramics.…”

“…In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. , Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. , Figure e shows the variation of the coercive field ( E c ) and remanent polarization ( P r ) of PIN-PMN-PT transparent ceramics. P r decreases from 45.0 to 30.0 μC/cm 2 with increasing Sm doping content, and for details, please refer to Table .…”

“…In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. 27,28 Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves.…”

“…Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. 28,29 Figure 2e shows the variation of the coercive field (E c ) and remanent polarization (P r ) of PIN-PMN-PT transparent ceramics. P r decreases from 45.0 to 30.0 μC/cm 2 with increasing Sm doping content, and for details, please refer to Table 1.…”

Sm-Doped PIN-PMN-PT Transparent Ceramics with High Curie Temperature, Good Piezoelectricity, and Excellent Electro-Optical Properties

“…It can be seen that all the transparent ceramics have saturated ferroelectric hysteresis and butterfly-shaped electric-field-induced strain curves, showing representative ferroelectric and piezoelectric performance. In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. , Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. , Figure e shows the variation of the coercive field ( E c ) and remanent polarization ( P r ) of PIN-PMN-PT transparent ceramics.…”

“…In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. , Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. , Figure e shows the variation of the coercive field ( E c ) and remanent polarization ( P r ) of PIN-PMN-PT transparent ceramics. P r decreases from 45.0 to 30.0 μC/cm 2 with increasing Sm doping content, and for details, please refer to Table .…”

“…In particular, the 1.0 mol % doped sample shows a larger negative strain, demonstrating the improved piezoelectric and ferroelectric properties. 27,28 Pb volatilization in the sintering process and non-equivalent valence ion doping will introduce vacancies, which will result in the formation of defect dipoles. Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves.…”

“…Then, an internal bias electric field will be formed due to defect dipoles and finally leads to the asymmetric of bipolar strain-electric-field curves. 28,29 Figure 2e shows the variation of the coercive field (E c ) and remanent polarization (P r ) of PIN-PMN-PT transparent ceramics. P r decreases from 45.0 to 30.0 μC/cm 2 with increasing Sm doping content, and for details, please refer to Table 1.…”

Sm-Doped PIN-PMN-PT Transparent Ceramics with High Curie Temperature, Good Piezoelectricity, and Excellent Electro-Optical Properties

“…As is well known, spontaneous polarization reversal is faster than that of defect dipoles under the same electric fields. 23,29) It means that the frequency of the electric field will affect the macroscopic performance of ferroelectric materials. Therefore, frequency-dependent hysteresis loops were studied as shown in Figs.…”

Effect of electric field frequency on double hysteresis loops and energy storage characteristics of Sm/Mn co-doped PMN-PT ferroelectric ceramics

A systematic investigation to establish a structure-property correlation in 0.65PMN–0.35PT ceramics