Fabrication of Textured 0.685TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] Electrostrictive Ceramics by Templated Grain Growth Using NaNbO[sub.3] Templates and Characterization of Their Electrical Properties

Electrostrictive materials based on (Na[sub.0.5]Bi[sub.0.5])TiO[sub.3] are promising lead-free candidates for high-precision actuation applications, yet their properties require further improvement. This study aims to enhance the electromechanical properties of a predominantly electrostrictive compo...

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Veröffentlicht in:	Crystals (Basel) 2024-10, Vol.14 (10)
Hauptverfasser:	Andleeb, Kiran, Trung, Doan Thanh, Fisher, John G, Tran, Tran Thi Huyen, Lee, Jong-Sook, Choi, Woo-Jin, Jo, Wook
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Schlagworte:	Activation energy Actuators Dielectrics Electric properties Electrical conductivity Technology application
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creator	Andleeb, Kiran Trung, Doan Thanh Fisher, John G Tran, Tran Thi Huyen Lee, Jong-Sook Choi, Woo-Jin Jo, Wook
description	Electrostrictive materials based on (Na[sub.0.5]Bi[sub.0.5])TiO[sub.3] are promising lead-free candidates for high-precision actuation applications, yet their properties require further improvement. This study aims to enhance the electromechanical properties of a predominantly electrostrictive composition, 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3], by using templated grain growth. Textured ceramics were prepared with 1~9 wt% NaNbO[sub.3] templates. A high Lotgering factor of 95% was achieved with 3 wt% templates and sintering at 1200 °C for 12 h. Polarization and strain hysteresis loops confirmed the ergodic nature of the system at room temperature, with unipolar strain significantly improving from 0.09% for untextured ceramics to 0.23% post-texturing. A maximum normalized strain, S[sub.max]/E[sub.max] (d[sub.33]*), of 581 pm/V was achieved at an electric field of 4 kV/mm for textured ceramics. Textured ceramics also showed enhanced performance over untextured ceramics at lower electric fields. The electrostrictive coefficient Q[sub.33] increased from 0.017 m[sup.4]C[sup.−2] for untextured ceramics to 0.043 m[sup.4]C[sup.−2] for textured ceramics, accompanied by reduced strain hysteresis, making the textured 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] composition suitable for high-precision actuation applications. Dielectric properties measured between −193 °C and 550 °C distinguished the depolarization, Curie–Weiss and Burns temperatures, and activation energies for polar nanoregion transitions and dc conduction. Dispersive dielectric constants were found to observe the “two” law exhibiting a temperature dependence double the value of the Curie–Weiss constant, with shifts of about 10 °C per frequency decade where the non-dispersive THz limit was identified.
doi_str_mv	10.3390/cryst14100861
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This study aims to enhance the electromechanical properties of a predominantly electrostrictive composition, 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3], by using templated grain growth. Textured ceramics were prepared with 1~9 wt% NaNbO[sub.3] templates. A high Lotgering factor of 95% was achieved with 3 wt% templates and sintering at 1200 °C for 12 h. Polarization and strain hysteresis loops confirmed the ergodic nature of the system at room temperature, with unipolar strain significantly improving from 0.09% for untextured ceramics to 0.23% post-texturing. A maximum normalized strain, S[sub.max]/E[sub.max] (d[sub.33]), of 581 pm/V was achieved at an electric field of 4 kV/mm for textured ceramics. Textured ceramics also showed enhanced performance over untextured ceramics at lower electric fields. The electrostrictive coefficient Q[sub.33] increased from 0.017 m[sup.4]C[sup.−2] for untextured ceramics to 0.043 m[sup.4]C[sup.−2] for textured ceramics, accompanied by reduced strain hysteresis, making the textured 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] composition suitable for high-precision actuation applications. Dielectric properties measured between −193 °C and 550 °C distinguished the depolarization, Curie–Weiss and Burns temperatures, and activation energies for polar nanoregion transitions and dc conduction. Dispersive dielectric constants were found to observe the “two” law exhibiting a temperature dependence double the value of the Curie–Weiss constant, with shifts of about 10 °C per frequency decade where the non-dispersive THz limit was identified.</description><identifier>ISSN: 2073-4352</identifier><identifier>EISSN: 2073-4352</identifier><identifier>DOI: 10.3390/cryst14100861</identifier><language>eng</language><publisher>MDPI AG</publisher><subject>Activation energy ; Actuators ; Dielectrics ; Electric properties ; Electrical conductivity ; Technology application</subject><ispartof>Crystals (Basel), 2024-10, Vol.14 (10)</ispartof><rights>COPYRIGHT 2024 MDPI AG</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,776,780,860,27901,27902</link.rule.ids></links><search><creatorcontrib>Andleeb, Kiran</creatorcontrib><creatorcontrib>Trung, Doan Thanh</creatorcontrib><creatorcontrib>Fisher, John G</creatorcontrib><creatorcontrib>Tran, Tran Thi Huyen</creatorcontrib><creatorcontrib>Lee, Jong-Sook</creatorcontrib><creatorcontrib>Choi, Woo-Jin</creatorcontrib><creatorcontrib>Jo, Wook</creatorcontrib><title>Fabrication of Textured 0.685TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] Electrostrictive Ceramics by Templated Grain Growth Using NaNbO[sub.3] Templates and Characterization of Their Electrical Properties</title><title>Crystals (Basel)</title><description>Electrostrictive materials based on (Na[sub.0.5]Bi[sub.0.5])TiO[sub.3] are promising lead-free candidates for high-precision actuation applications, yet their properties require further improvement. This study aims to enhance the electromechanical properties of a predominantly electrostrictive composition, 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3], by using templated grain growth. Textured ceramics were prepared with 1~9 wt% NaNbO[sub.3] templates. A high Lotgering factor of 95% was achieved with 3 wt% templates and sintering at 1200 °C for 12 h. Polarization and strain hysteresis loops confirmed the ergodic nature of the system at room temperature, with unipolar strain significantly improving from 0.09% for untextured ceramics to 0.23% post-texturing. A maximum normalized strain, S[sub.max]/E[sub.max] (d[sub.33]), of 581 pm/V was achieved at an electric field of 4 kV/mm for textured ceramics. Textured ceramics also showed enhanced performance over untextured ceramics at lower electric fields. The electrostrictive coefficient Q[sub.33] increased from 0.017 m[sup.4]C[sup.−2] for untextured ceramics to 0.043 m[sup.4]C[sup.−2] for textured ceramics, accompanied by reduced strain hysteresis, making the textured 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] composition suitable for high-precision actuation applications. Dielectric properties measured between −193 °C and 550 °C distinguished the depolarization, Curie–Weiss and Burns temperatures, and activation energies for polar nanoregion transitions and dc conduction. 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This study aims to enhance the electromechanical properties of a predominantly electrostrictive composition, 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3], by using templated grain growth. Textured ceramics were prepared with 1~9 wt% NaNbO[sub.3] templates. A high Lotgering factor of 95% was achieved with 3 wt% templates and sintering at 1200 °C for 12 h. Polarization and strain hysteresis loops confirmed the ergodic nature of the system at room temperature, with unipolar strain significantly improving from 0.09% for untextured ceramics to 0.23% post-texturing. A maximum normalized strain, S[sub.max]/E[sub.max] (d[sub.33]*), of 581 pm/V was achieved at an electric field of 4 kV/mm for textured ceramics. Textured ceramics also showed enhanced performance over untextured ceramics at lower electric fields. The electrostrictive coefficient Q[sub.33] increased from 0.017 m[sup.4]C[sup.−2] for untextured ceramics to 0.043 m[sup.4]C[sup.−2] for textured ceramics, accompanied by reduced strain hysteresis, making the textured 0.685(Na[sub.0.5]Bi[sub.0.5])TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] composition suitable for high-precision actuation applications. Dielectric properties measured between −193 °C and 550 °C distinguished the depolarization, Curie–Weiss and Burns temperatures, and activation energies for polar nanoregion transitions and dc conduction. Dispersive dielectric constants were found to observe the “two” law exhibiting a temperature dependence double the value of the Curie–Weiss constant, with shifts of about 10 °C per frequency decade where the non-dispersive THz limit was identified.</abstract><pub>MDPI AG</pub><doi>10.3390/cryst14100861</doi></addata></record>
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title	Fabrication of Textured 0.685TiO[sub.3]-0.065BaTiO[sub.3]-0.25SrTiO[sub.3] Electrostrictive Ceramics by Templated Grain Growth Using NaNbO[sub.3] Templates and Characterization of Their Electrical Properties
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