Enhanced Dielectric and Ferroelectric Properties of Donor (W6+, Eu3+) Substituted SBT Ferroelectric Ceramics

Coondoo, Indrani; Panwar, Neeraj

doi:10.5772/13297

Cited by 4 publications

(3 citation statements)

References 99 publications

(159 reference statements)

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“…[30,34] PVDFbased polymers are usually crystallized into phases of various phases. [51][52][53] Particularly, the a and β phases are the main phases in PVDF polymers. The β phase has well ordered -CF 2dipoles causing piezoelectric and ferroelectric properties, while the a phase resides in paraelectric.…”

Section: Resultsmentioning

confidence: 99%

Ferroelectric Polymer Nanofibers Reminiscent of Morphotropic Phase Boundary Behavior for Improved Piezoelectric Energy Harvesting

Park

Lim

Cho

et al. 2022

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Ferroelectric and piezoelectric polymers have attracted great attention from many research and engineering fields due to its mechanical robustness and flexibility as well as cost‐effectiveness and easy processibility. Nevertheless, the electrical performance of piezoelectric polymers is very hard to reach that of piezoelectric ceramics basically and physically, even in the case of the representative ferroelectric polymer, poly(vinylidene fluoride‐co‐trifluoroethylene) (P(VDF‐TrFE)). Very recently, the concept for the morphotropic phase boundary (MPB), which has been exclusive in the field of high‐performance piezoelectric ceramics, has been surprisingly confirmed in P(VDF‐TrFE) piezoelectric copolymers by the groups. This study demonstrates the exceptional behaviors reminiscent of MPB and relaxor ferroelectrics in the feature of widely utilized electrospun P(VDF‐TrFE) nanofibers. Consequently, an energy harvesting device that exceeds the performance limitation of the existing P(VDF‐TrFE) materials is developed. Even the unpoled MPB‐based P(VDF‐TrFE) nanofibers show higher output than the electrically poled normal P(VDF‐TrFE) nanofibers. This study is the first step toward the manufacture of a new generation of piezoelectric polymers with practical applications.

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Section: Resultsmentioning

confidence: 99%

Ferroelectric Polymer Nanofibers Reminiscent of Morphotropic Phase Boundary Behavior for Improved Piezoelectric Energy Harvesting

Park

Lim

Cho

et al. 2022

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“…At the same time, the higher value of P r in the SBTW ceramic samples compared to the pure SBT ceramic samples can be explained on the basis of the formation of cation vacancies in the SBTW system [30]. The substitution of W 6+ ions at the Ta 5+ ions sites can suppress the concentration of the oxygen vacancies in the SBTW system, which can reduce the pinning effect on the domain walls and enhance the P r and reduce the E c values [43]. and (c) SBTW ceramic samples.…”

Section: Leakage Current Analysismentioning

confidence: 92%

Electrical and ferroelectric studies of the 2-layered SrBi2Ta2O9 based ceramics

Swain

Kumar

Choudhary

2015

Physica B: Condensed Matter

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“…Each these contributions suffer short-distortions in response to alternating applied electric field on different time scale, or equivalent, over a wide frequency range leading to changes in the polarization which can be characterized inserting a quantity termed as the dielectric permittivity ε. It is to be expected given the nature of the excitation that ε shows different dispersion laws characterized by a threshold frequency labeling each contribution mechanism depends on the nature of dipoles [155]. If the dipole contribution oscillate and experiments a restoring force, a relaxation behaviour is found in the dielectric permittivity.…”

Section: Dielectric Dispersionmentioning

confidence: 99%

Theoretical and experimental investigation on the visible-light controlled functional properties in charged domain wall ferroelectrics

Ordoñez Pimentel

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(English) Optical control of ferroelectric properties has been attracted a growing interest as an alternative to the conventional control by applied electric fields. However, the major drawback for achieving an effective reversible optical control of domain rearrangement in conventional ferroelectrics lies in their wide optical band gap. Recent researches has reported a new form to optically control of electric polarization and its related properties by using visible light. Specifically, a light-induced local movement of domain walls was achieved, whose effects shown that the photoresponse at both local and macroscopic scales is wavelength-independent. This new phenomenon of light-matter coupling has a non-negligible time response and no light power threshold was observed. Such characteristics are observed through the crystal lattice structure, photo-induced strain and dielectric permittivity. In addition, experimental evidences suggest that the light-activated phenomenon seems to be correlated with the existence of atypical ferroelectric interfaces, known as charged domain walls, whose principal signature is to host free and bound electric charge. Undoubtedly, this phenomenon offers new possibilities for technological applications that are as yet unexplored. This thesis focuses in overcome some questions that remains to be solved concerning to this light-activated phenomenon. That is: What is the physical insight about the photo-ferroelectric response? Is the extension towards polycrystalline materials feasible? Are there other physical properties different from those already controlled enable to be modified? To answer these question, the thesis divides into two parts: one theoretical and another one experimental. In the first part, a phenomenology model describing the visible light-induced photoresponse is developed, which assumes that visible light modifies charged domain wall compensation so that the built-in electric fields in the system changes, thereby triggering the domain wall motion. As a result, a rearrangement of the domain structure occurs, leading to a macroscopic polarization variation and, consequently, the related properties. Regarding to extension towards polycrystalline materials, it is successfully proved that photoresponse can be observed by the optical control of the photo-induced strain. Furthermore, it is proved the hypothesis that the existence of charged domain walls is a requirement for the photoresponse to manifest. Finally, the thesis reports for first time that the mechanical response of a ferrolectric ceramics can be modulated by visible light, highlighting the role of the charged domain walls. In a broader perspective, this work contributes to extending the fundamental knowledge based on light-ferroelectric coupling, opening new opportunities to speed up the development of a new generation of contact-less photoelectronic devices. (Español) El control óptico de las propiedades ferroeléctricas tiene un creciente interés como alternativa viable al control convencional mediante campos eléctricos. El mayor inconveniente para conseguir un control óptico efectivo y reversible de la configuración de dominios ferroeléctricos radica en que los ferroeléctricos convencionales tienen un alto gap de banda. Investigaciones recientes han reportado una nueva forma de controlar ópticamente la polarización eléctrica y sus propiedades relacionadas mediante el uso de luz visible. En particular, se ha conseguido lograr un movimiento local de las paredes del dominio inducido por la luz, cuyos efectos mostraron que la fotorrespuesta a escala local y macroscópica es independiente de la longitud de onda en el espectro visible. Este nuevo fenómeno de acoplamiento luz-materia tiene una respuesta temporal no despreciable y no se observó ningún umbral de potencia de luz. Tales características se han observado a través de la deformación fotoinducida y cambios en la permitividad dieléctrica con luz. Además, las evidencias experimentales sugieren que el fenómeno activado por la luz parece estar correlacionado con la existencia de interfaces ferroeléctricas atípicas, conocidas como paredes de dominios cargadas, cuya característica principal es albergar carga libre y ligada. Sin duda, este fenómeno ofrece nuevas posibilidades de aplicaciones tecnológicas aún inexploradas. Esta tesis se centra en superar algunas cuestiones que quedan por resolver en relación con este fenómeno activado por la luz. Esto es, ¿Cuál es el origen físico de la respuesta foto-ferroeléctrica? ¿Es factible la extensión de este fenómeno a materiales policristalinos? ¿Existen otras propiedades físicas distintas a las ya controladas que se puedan modificar con luz? Para responder a estas preguntas, la tesis se divide en dos partes: una teórica y otra experimental. En la primera parte, se desarrolla un modelo fenomenológico que describe la fotorrespuesta inducida por la luz visible, asumindo que la luz visible modifica la compensación de la pared de los dominios cargados produciendo un cambio en los campos eléctricos internos del sistema, lo que desencadena el movimiento de las paredes de dominio. Como resultado, se produce un reordenamiento de la estructura del dominio, lo que conduce a una variación de la polarización macroscópica y, en consecuencia, de las propiedades relacionadas con ésta. En cuanto a la extensión hacia materiales policristalinos, en la tesis se demuestra con éxito que la fotorrespuesta es observable en policristales mediante el control óptico de la deformación fotoinducida. Además, se prueba la hipótesis de que la existencia de paredes de dominio cargadas es un requisito para que se manifieste la fotorrespuesta. Finalmente, la tesis reporta, por primera vez, que la respuesta mecánica de una cerámica ferroeléctrica puede ser modulada por luz visible, destacando el papel de las paredes de dominio cargadas. Desde una perspectiva más amplia, este trabajo contribuye a ampliar los conocimientos fundamentales basados en el acoplamiento entre luz visible y materiales ferroeléctricos, abriendo nuevas oportunidades para acelerar el desarrollo de una nueva generación de dispositivos fotocontrolados.

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Enhanced Dielectric and Ferroelectric Properties of Donor (W6+, Eu3+) Substituted SBT Ferroelectric Ceramics

Cited by 4 publications

References 99 publications

Ferroelectric Polymer Nanofibers Reminiscent of Morphotropic Phase Boundary Behavior for Improved Piezoelectric Energy Harvesting

Ferroelectric Polymer Nanofibers Reminiscent of Morphotropic Phase Boundary Behavior for Improved Piezoelectric Energy Harvesting

Electrical and ferroelectric studies of the 2-layered SrBi2Ta2O9 based ceramics

Theoretical and experimental investigation on the visible-light controlled functional properties in charged domain wall ferroelectrics

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