Estudo da polarização ferroelétrica no copolímero P (VDF/TrFE) / Study of ferroelectric polarization in P(VDF/TrFE) copolymer

Alves, Neri

29 April 1992

Usando-se a técnica do triodo de corona com corrente constante estudaram-se as propriedades ferroelétricas dos copolímeros P(VDF-TrFE) contendo diferentes teores de VDF. Descrevem-se as metodologias usadas na preparação de amostras por solução, a caracterização por raios X e DSC e a determinação do grau de cristalinidade. Apresentam-se o princípio de funcionamento da técnica do triodo de corona com corrente constante e a equivalência das curvas de potencial de superfície com as curvas de histerese. Mostra-se que a condução elétrica pode ser desprezada quando as medidas são realizadas em atmosfera com baixo valor de umidade. O valor do campo coercivo e da polarização remanente foram determinados a partir das curvas de subida do potencial de superfície, sendo o valor da polarização diretamente proporcional ao grau de cristalinidade das amostras. Esses resultados foram analisados supondo-se que os filmes de P(VDF-TrFE) podem ter duas fases cristalinas. Também são discutidos os modelos teóricos usados para interpretar as curvas de subida do potencial de superfície. / Ferroelectric properties of P(VDF-TrFE) copolymers having different contents of VDF were investigated using the corona triode with constant current. The casting procedure for the sample preparation, the characterization by X rays and DSC, and the determination of the degree of crystalinity were presented. The corona triode method allowing to charge samples with a Constant current and the equivalence between the potential buildup curves and hysteresis curves are presented. The coercive field and the remanent polarization were determined from the potential buildup curves and it was found that the polarization is linearly dependent on the degree of crystalinity. Results were discussed taking into account two different crystaline phases which could exists in P(VDF-TrFE). Also, it was presented theoretical models aiming to fit the potential buildup curves.

Constant current

Corrente constante

Ferroelectric polarization

P(VDF-TrFE)

P(VDF-TrFE)

Polarização ferroelétrica

Estudo da polarização ferroelétrica no copolímero P (VDF/TrFE) / Study of ferroelectric polarization in P(VDF/TrFE) copolymer

Neri Alves

29 April 1992

Usando-se a técnica do triodo de corona com corrente constante estudaram-se as propriedades ferroelétricas dos copolímeros P(VDF-TrFE) contendo diferentes teores de VDF. Descrevem-se as metodologias usadas na preparação de amostras por solução, a caracterização por raios X e DSC e a determinação do grau de cristalinidade. Apresentam-se o princípio de funcionamento da técnica do triodo de corona com corrente constante e a equivalência das curvas de potencial de superfície com as curvas de histerese. Mostra-se que a condução elétrica pode ser desprezada quando as medidas são realizadas em atmosfera com baixo valor de umidade. O valor do campo coercivo e da polarização remanente foram determinados a partir das curvas de subida do potencial de superfície, sendo o valor da polarização diretamente proporcional ao grau de cristalinidade das amostras. Esses resultados foram analisados supondo-se que os filmes de P(VDF-TrFE) podem ter duas fases cristalinas. Também são discutidos os modelos teóricos usados para interpretar as curvas de subida do potencial de superfície. / Ferroelectric properties of P(VDF-TrFE) copolymers having different contents of VDF were investigated using the corona triode with constant current. The casting procedure for the sample preparation, the characterization by X rays and DSC, and the determination of the degree of crystalinity were presented. The corona triode method allowing to charge samples with a Constant current and the equivalence between the potential buildup curves and hysteresis curves are presented. The coercive field and the remanent polarization were determined from the potential buildup curves and it was found that the polarization is linearly dependent on the degree of crystalinity. Results were discussed taking into account two different crystaline phases which could exists in P(VDF-TrFE). Also, it was presented theoretical models aiming to fit the potential buildup curves.

Corrente constante

P(VDF-TrFE)

Polarização ferroelétrica

Constant current

Ferroelectric polarization

P(VDF-TrFE)

Estudo morfológico do PVDF e de blendas PVDF/P(VDF-TrFE). / Morphological study of PVDF and PVDF/P(VDF-TrFE) blends.

Capitão, Rosa Cristina

08 March 2002

O poli(fluoreto de vinilideno) (PVDF) é um polímero semicristalino que quando cristalizado a partir da fusão à temperaturas acima de 155°C apresenta uma variada morfologia cristalina, constituída por esferulitos anelados, não anelados e mistos. Abaixo dessa temperatura somente os esferulitos anelados são formados. Neste trabalho foi realizado um estudo morfológico do PVDF, procurando verificar a relação entre o tipo de esferulito formado e a fase cristalina predominante em suas lamelas. Foi verificado, por espectroscopia no infravermelho, que os esferulitos anelados apresentam exclusivamente a fase alfa, quando a cristalização ocorre a temperaturas inferiores a 155°C. Temperaturas superiores a essa induzem nessas estruturas uma transformação de fase alfa em gama, que aumenta a quantidade de fase gama com o tempo de cristalização. A taxa com que essa transformação ocorre aumenta com a temperatura de cristalização. Os esferulitos não anelados são constituídos predominantemente pela fase gama, cristalizada diretamente do fundido, com pequenas inclusões de fase alfa. O processo de fusão dos diferentes esferulitos, observado por microscopia ótica (MOLP) e medidas calorimétricas (DSC), mostraram que a temperatura de fusão da fase gama originada da transformação de fase é 8°C superior à daquela cristalizada diretamente do fundido. Micrografias de amostras aquecidas até 186°C e rapidamente resfriadas permitiram visualizar as regiões dos esferulitos anelados que sofreram a transformação de fase alfa em gama, para diferentes tempos e temperaturas de cristalização. Foi realizado, ainda, um estudo morfológico de blendas PVDF/P(VDF-TrFE), com diferentes composições e com o copolímero contendo 72% em mol de VDF. Análises térmicas (DSC) verificaram que os componentes da blenda são imiscíveis na fase cristalina, quando a cristalização ocorre a partir da fusão. Porém, micrografias obtidas por MOLP e MEV indicaram a presença de moléculas do copolímero nas regiões interlamelares dos esferulitos formados durante a cristalização do PVDF. Esse resultado sugere a miscibilidade entre os componentes no estado líquido, e que esta mistura íntima deve permanecer durante a cristalização, resultando na miscibilidade dos componentes na fase amorfa. / Poly(vinylidene fluoride) (PVDF) is a semi crystalline polymer that, when is crystallized from the melt at temperatures above 155°C, it presents a multiform morphology composed of ringed, non-ringed and mixed spherulites. Above this temperature only ringed spherulites are formed. In this work a morphological study of PVDF was performed, endeavoring to investigate the relation between the type of spherulite formed and the dominant crystalline phase in their lamellas. Infrared spectroscopy showed that the ringed spherulites are formed exclusively by the alpha phase when crystallization takes place at temperatures below 155°C. Higher temperatures induce a solid-state alpha in gamma phase transformation in these structures, increasing the amount of gamma phase with crystallization time. The rate at which this transformation takes place increases with crystallization temperature. The non-ringed spherulites consist predominantly of the gamma phase, crystallized from the melt, with small alpha phase inclusions. The melt process of the different spherulites, observed by optical microscopy (MOLP) and calorimetric measurements (DSC) showed that the melt temperature of the gamma phase originated from the phase transition is 8°C higher than that crystallized directly from the melt. Micrographs of samples heated up to 186°C and quickly cooled allowed visualization of the ringed spherulite regions, which underwent the alpha in gamma phase transformation at different crystallization times and temperatures. In addition, it was observed a morphological study of blends, with different compositions and the copolymer containing 72 mol% of VDF. Thermal analysis (DSC) showed that blend components are immiscible on crystalline phase, when the crystallization from the melt occurs. However, micrographs obtained from MOLP and MEV indicated the presence of copolymer on spherulites interlamellar regions, formed during PVDF crystallization. This result suggests miscibility between the components in the liquid state, and this intimate mixture must remain during crystallization, resulting in miscibility of the components in amorphous phase.

miscibilidade

miscibility

morfologia

morphology

PVDF

PVDF/P(VDF-TrFE)

Estudo morfológico do PVDF e de blendas PVDF/P(VDF-TrFE). / Morphological study of PVDF and PVDF/P(VDF-TrFE) blends.

Rosa Cristina Capitão

08 March 2002

O poli(fluoreto de vinilideno) (PVDF) é um polímero semicristalino que quando cristalizado a partir da fusão à temperaturas acima de 155°C apresenta uma variada morfologia cristalina, constituída por esferulitos anelados, não anelados e mistos. Abaixo dessa temperatura somente os esferulitos anelados são formados. Neste trabalho foi realizado um estudo morfológico do PVDF, procurando verificar a relação entre o tipo de esferulito formado e a fase cristalina predominante em suas lamelas. Foi verificado, por espectroscopia no infravermelho, que os esferulitos anelados apresentam exclusivamente a fase alfa, quando a cristalização ocorre a temperaturas inferiores a 155°C. Temperaturas superiores a essa induzem nessas estruturas uma transformação de fase alfa em gama, que aumenta a quantidade de fase gama com o tempo de cristalização. A taxa com que essa transformação ocorre aumenta com a temperatura de cristalização. Os esferulitos não anelados são constituídos predominantemente pela fase gama, cristalizada diretamente do fundido, com pequenas inclusões de fase alfa. O processo de fusão dos diferentes esferulitos, observado por microscopia ótica (MOLP) e medidas calorimétricas (DSC), mostraram que a temperatura de fusão da fase gama originada da transformação de fase é 8°C superior à daquela cristalizada diretamente do fundido. Micrografias de amostras aquecidas até 186°C e rapidamente resfriadas permitiram visualizar as regiões dos esferulitos anelados que sofreram a transformação de fase alfa em gama, para diferentes tempos e temperaturas de cristalização. Foi realizado, ainda, um estudo morfológico de blendas PVDF/P(VDF-TrFE), com diferentes composições e com o copolímero contendo 72% em mol de VDF. Análises térmicas (DSC) verificaram que os componentes da blenda são imiscíveis na fase cristalina, quando a cristalização ocorre a partir da fusão. Porém, micrografias obtidas por MOLP e MEV indicaram a presença de moléculas do copolímero nas regiões interlamelares dos esferulitos formados durante a cristalização do PVDF. Esse resultado sugere a miscibilidade entre os componentes no estado líquido, e que esta mistura íntima deve permanecer durante a cristalização, resultando na miscibilidade dos componentes na fase amorfa. / Poly(vinylidene fluoride) (PVDF) is a semi crystalline polymer that, when is crystallized from the melt at temperatures above 155°C, it presents a multiform morphology composed of ringed, non-ringed and mixed spherulites. Above this temperature only ringed spherulites are formed. In this work a morphological study of PVDF was performed, endeavoring to investigate the relation between the type of spherulite formed and the dominant crystalline phase in their lamellas. Infrared spectroscopy showed that the ringed spherulites are formed exclusively by the alpha phase when crystallization takes place at temperatures below 155°C. Higher temperatures induce a solid-state alpha in gamma phase transformation in these structures, increasing the amount of gamma phase with crystallization time. The rate at which this transformation takes place increases with crystallization temperature. The non-ringed spherulites consist predominantly of the gamma phase, crystallized from the melt, with small alpha phase inclusions. The melt process of the different spherulites, observed by optical microscopy (MOLP) and calorimetric measurements (DSC) showed that the melt temperature of the gamma phase originated from the phase transition is 8°C higher than that crystallized directly from the melt. Micrographs of samples heated up to 186°C and quickly cooled allowed visualization of the ringed spherulite regions, which underwent the alpha in gamma phase transformation at different crystallization times and temperatures. In addition, it was observed a morphological study of blends, with different compositions and the copolymer containing 72 mol% of VDF. Thermal analysis (DSC) showed that blend components are immiscible on crystalline phase, when the crystallization from the melt occurs. However, micrographs obtained from MOLP and MEV indicated the presence of copolymer on spherulites interlamellar regions, formed during PVDF crystallization. This result suggests miscibility between the components in the liquid state, and this intimate mixture must remain during crystallization, resulting in miscibility of the components in amorphous phase.

miscibilidade

morfologia

PVDF

PVDF/P(VDF-TrFE)

miscibility

morphology

Transport and Fatigue Properties of Ferroelectric Polymer P(VDF-TrFE) For Nonvolatile Memory Applications

Hanna, Amir

06 1900

Organic ferroelectrics polymers have recently received much interest for use in nonvolatile memory devices. The ferroelectric copolymer poly(vinylidene fluoride- trifluoroethylene) , P(VDF-TrFE), is a promising candidate due to its relatively high remnant polarization, low coercive field, fast switching times, easy processability, and low Curie transition. However, no detailed study of charge injection and current transport properties in P(VDF-TrFE) have been reported in the literature yet. Charge injection and transport are believed to affect various properties of ferroelectric films such as remnant polarization values and polarization fatigue behavior.. Thus, this thesis aims to study charge injection in P(VDF-TrFE) and its transport properties as a function of electrode material. Injection was studied for Al, Ag, Au and Pt electrodes. Higher work function metals such as Pt have shown less leakage current compared to lower work function metals such as Al for more than an order of magnitude. That implied n-type conduction behavior for P(VDF-TrFE), as well as electrons being the dominant injected carrier type. Charge transport was also studied as a function of temperature, and two major transport regimes were identified: 1) Thermionic emission over a Schottky barrier for low fields (E < 25 MV/m). 2) Space-Charge-Limited regime at higher fields (25 < E <120 MV/m). We have also studied the optical imprint phenomenon, the polarization fatigue resulting from a combination of broad band optical illumination and DC bias near the switching field. A setup was designed for the experiment, and validated by reproducing the reported effect in polycrystalline Pb(Zr,Ti)O3 , PZT, film. On the other hand, P(VDF-TrFE) film showed no polarization fatigue as a result of optical imprint test, which could be attributed to the large band gap of the material, and the low intensity of the UV portion of the arc lamp white light used for the experiment. Results suggest using high work function metals for a memory application, as lower leakage would enhance fatigue endurance for P(VDF-TrFE) film.

Transport properties

Ferroelectric polymers

P(VDF-TrFE)

Memory application

Fatigue

Élaboration de films nanocomposites hybrides P(VDF-TrFE)/nanocristaux, et intégration dans des dispositifs microstructurés / Preparation of polymeric hybrid nanocomposite films based on P(VDF-TrFE)/nanocrystals, and integration in microstructured devices

Nguyen, Van Son

17 September 2012

Les objectifs de ce travail consistent à développer de nouveaux matériaux souples hybrides organiques/inorganiques en vue d'application pour des microsystèmes. Cette étude comprend l'élaboration et la caractérisation de nanocomposites à matrices polymères ferroélectriques P(VDF-TrFE), matériaux potentiels pour les applications à base de films minces, et de différents types de nanoparticules: ZnO, LiNbO3 (piézoélectriques) et Al2O3 (non-piézoélectriques). Les protocoles de dispersion ultrasoniques des nanoparticules dans des solvants et des solutions polymères ont été optimisés, afin de disperser de façon homogène des clusters de nanocristaux dans la matrice copolymère. Les films d'épaisseurs contrôlées de 0.1 µm à 100 µm ont été fabriqués par spin-coating et enduction, avec une qualité de surface adaptée aux micro-technologies. L'étude de la morphologie et de la cristallinité de P(VDF-trFE) a montré leur préservation en présence de nanoparticules jusqu'à 10 wt.%. Les nanocomposites gardent ainsi des propriétés piézoélectriques élevées tout en montrant un renforcement allant jusqu'à 30 % des propriétés mécaniques avec 10 wt.% de ZnO ou Al2O3. De plus, une augmentation des constantes élastiques avec la diminution de la taille des clusters de nanoparticules a été observée. Les films nanocomposites sur substrats ou autosupportés chargés jusqu'à 10 wt.% ont été polarisés avec succès par Corona sans contact. Des protocoles spécifiques pour réaliser des microdispositifs par photolithographie sur films nanocomposites tout en conservant les activités piézoélectriques des matériaux ont été développés. La caractérisation des dispositifs à ondes acoustiques réalisés est aussi présentée / The objective of this work is to develop flexible organic/inorganic hybrid materials for application in microsystems. This study included the preparation and characterization of nanocomposites based on ferroelectric polymer matrix P(VDF-TrFE), potential materials for applications based on thin films on substrates, and different types of nanoparticles: ZnO, LiNbO3 (piezoelectric) and Al2O3 (non-piezoelectric). The protocols of the ultrasonic dispersion of nanoparticles in solvents and polymeric solutions are optimized, allowing dispersing quite homogeneously clusters of nanocrystals in the matrix copolymer. Films of controlled thickness between 0.1 µm and 100 µm were fabricated by spin-coating and doctor blade coating with surface quality suitable for micro-technologies. Morphology and crystallinity of P(VDF-TrFE) are preserved in the presence of up to 10 wt.% of nanoparticles. Thus nanocomposites keep high piezoelectric properties and show an increased up to 30% of the mechanical properties for 10 wt.% ZnO or Al2O3. In addition, the increase in elastic constant with decreasing cluster size of nanoparticles was observed. Nanocomposite films on substrates or free-standing filled up to 10 wt.% were successfully polarized by corona without contact. Specific procedures for preparing microdevices by photolithography on nanocomposite polymer films, while keeping piezoelectric activities of materials, have been developed. The characterization of realized acoustic wave devices is also presented

P(VDF-TrFE)

Nanoparticules

Nanocomposite

Propriétés piézoélectriques

Dispositifs microstructurés

P(VDF-TrFE)

Nanoparticles

Nanocomposite

Piezoelectric properties

Microstructured devices

620.5

Coupling of the electrical, mechanical and optical response in polymer/liquid-crystal composites

Ganesan, Lakshmi Meena

January 2010

Micrometer-sized liquid-crystal (LC) droplets embedded in a polymer matrix may enable optical switching in the composite film through the alignment of the LC director along an external electric field. When a ferroelectric material is used as host polymer, the electric field generated by the piezoelectric effect can orient the director of the LC under an applied mechanical stress, making these materials interesting candidates for piezo-optical devices. In this work, polymer-dispersed liquid crystals (PDLCs) are prepared from poly(vinylidene fluoride-trifluoroethylene) (P(VDF-TrFE)) and a nematic liquid crystal (LC). The anchoring effect is studied by means of dielectric relaxation spectroscopy. Two dispersion regions are observed in the dielectric spectra of the pure P(VDF-TrFE) film. They are related to the glass transition and to a charge-carrier relaxation, respectively. In PDLC films containing 10 and 60 wt% LC, an additional, bias-field-dependent relaxation peak is found that can be attributed to the motion of LC molecules. Due to the anchoring effect of the LC molecules, this relaxation process is slowed down considerably, when compared with the related process in the pure LC. The electro-optical and piezo-optical behavior of PDLC films containing 10 and 60 wt% LCs is investigated. In addition to the refractive-index mismatch between the polymer matrix and the LC molecules, the interaction between the polymer dipoles and the LC molecules at the droplet interface influences the light-scattering behavior of the PDLC films. For the first time, it was shown that the electric field generated by the application of a mechanical stress may lead to changes in the transmittance of a PDLC film. Such a piezo-optical PDLC material may be useful e.g. in sensing and visualization applications. Compared to a non-polar matrix polymer, the polar matrix polymer exhibits a strong interaction with the LC molecules at the polymer/LC interface which affects the electro-optical effect of the PDLC films and prevents a larger increase in optical transmission. / Mikrometer-große, in eine Polymermatrix eingebettete Flüssigkristall-Tröpfchen können als elektro-optische Lichtventile fungieren, da die Ausrichtung der Flüssigkristalle durch ein externes elektrisches Feld verändert werden kann. Wird nun ein ferroelektrisches Polymer als Matrix verwendet, so kann das durch den piezoelektrischen Effekt erzeugte und von der äußeren mechanischen Spannung abhängige elektrische Feld den Flüssigkristall ausrichten. Solche Materialien können daher als piezo-optische Lichtventile eingesetzt werden. Im Rahmen dieser Arbeit wurden PDLCs (polymer-dispersed liquid crystals) durch Einbettung von nematischen Flüssigkristallen in Poly(Vinylidenefluoride-Trifluorethylene) (P(VDF-TrFE)) erzeugt. Die Wechselwirkungen an der Grenzfläche zwischen Flüssigkristall und Polymer wurden mittels dielektrischer Spektroskopie untersucht. Im dielektrischen Spektrum des reinen P(VDF-TrFE) wurden zwei Dispersions-Regionen beobachtet, welche vom Glasübergang und einer Ladungsträgerrelaxation des Polymers herrühren. PDLC Folien mit unterschiedlichen Anteilen von Flüssigkristall-Tröpfchen (10 bzw. 60 Gewichtsprozente) zeigten beim Anlegen eines elektrischen Wechselfelds zusatzliche Relaxationseffekte, welche der Bewegung der eingebetteten Flüssigkristall-Moleküle zugeordnet werden konnten. Durch die Einlagerung der Flüssigkristall-Moleküle weist die Struktur eine Relaxation auf, die gegenüber vergleichbaren Prozessen im reinen Flüssigkristall deutlich verlangsamt ist. Des weiteren wurde das elektrooptische und piezo-optische Verhalten der mit 10 und 60 Gewichtsprozent Flüssigkristall geladenen Folien untersucht. Die Lichtstreuung hängt dabei ab von der Fehlanpassung der Brechungsindizes von Polymermatrix und Flüssigkristallen sowie von den Wechselwirkungen der Polymerdipole mit den Flüssigkristall-Molekülen an der Tröpfchenoberfläche. Es konnte erstmalig gezeigt werden, dass die Lichtdurchlässigkeit der PDLC-Folien durch eine externe mechanische Spannung gesteuert werden kann. Dieser Effekt macht das piezo-optische PDLC-Material für die Verwendung in Optik- und Sensoranwendungen interessant. Im Vergleich mit unpolaren Wirtspolymeren zeigen polare Wirtsmaterialien eine deutlich stärkere Wechselwirkung zwischen den Flüssigkristall-Molekülen an der Polymer/Flüssigkristall-Grenzfläche, welche den elektrooptischen Effekt beeinflusst und so die maximale transmissions änderung reduziert.

PDLC

P(VDF-TrFE)

nematic LC

piezo-optisch

elektro-optisch

PDLC

P(VDF-TrFE)

nematic LC

piezo-optical

electro-optical

Physics

Élaboration de membranes polymères piézoélectriques souples en vue d’applications biomédicales / Preparation of flexible piezoelectric polymeric membranes for biomedical applications

Thevenot, Camille

06 December 2017

Le travail présenté ici porte sur la réalisation d’un matériau polymère piézoélectrique destiné à être l’élément sensible d’un capteur de déformation de tissus biologiques. Cela comprend notamment l’étude de l’assouplissement du copolymère P(VDF-TrFE) nécessaire pour se rapprocher des propriétés mécaniques d’une artère, sans dégrader son coefficient piézoélectrique. Des films de P(VDF-TrFE) plastifiés avec du phtalate de diéthyle (DEP) ont été réalisés selon différents protocoles incluant enduction ou spin-coating et polarisation sous haute tension pour activer les propriétés ferroélectriques. Selon les conditions d’élaboration, deux structures distinctes de films ont été obtenues avec des propriétés physiques propres à chacune. Dans le premier type de film, l’étude de la morphologie et des courbes d’hystérésis polarisation-champ électrique a permis de mettre en évidence une nouvelle structuration du matériau, avec la démixtion du plastifiant dans la matrice. Le champ coercitif est dans ce cas fortement abaissé ce qui permet une réduction de la haute tension de polarisation nécessaire allant jusqu’à 40%, même lorsque que le film ne contient plus que 50wt% de P(VDF-TrFE). Le second type de film, obtenu après recuit à plus basse température, présente au contraire une structure quasi homogène et des propriétés proches d’une loi de mélange. Le champ coercitif reste comparable à celui du P(VDF-TrFE) pur mais la flexibilité du matériau est fortement accrue. L’étude des propriétés mécaniques a montré que le plastifiant peut réduire le module de Young du copolymère à 40MPa avec 30wt% de DEP dans le film. De surcroit la polarisation rémanente et le coefficient piézoélectrique sont également renforcés. Des tests in vitro et in vivo, réalisés sur des artères, de capteurs basés sur ces derniers films ont démontré le haut potentiel du matériau à détecter des déformations de tissus mous et à fonctionner aux fréquences biologiques humaines / The work presented here focuses on the preparation of a piezoelectric polymer material aimed to be the sensitive element of a strain sensor of biological tissues. This includes the study of the softening of the copolymer P(VDF-TrFE) necessary to be close of the mechanical properties of an artery, without reducing the piezoelectric coefficient. Plasticized P(VDF-TrFE) films with diethyl phthalate (DEP) were made according to different protocols including doctor blade technique or spin-coating and polarization under high voltage to activate the ferroelectric properties. Depending on the preparation conditions, two distinct structures were obtained with physical properties specific to each of them. For the first type of film, the study of the morphology and the hysteresis loops polarization-electric field showed a new structure of the material, with a demixing of the plasticizer in the matrix. In this case, the coercive field is strongly reduced which allows a decrease of the required high polarization voltage up to 40%, even if the film only contains 50wt% of P(VDF-TrFE). The second type of film, obtained after an annealing at lower temperature, has an almost homogeneous structure and properties close to a mixing law. The coercive field remains comparable to that of the pure P(VDF-TrFE) but the flexibility of the material is greatly increased. The study of the mechanical properties showed that the plasticizer can reduce the Young modulus to 40MPa for 30wt% of DEP in the film. In addition, the remanent polarization and the piezoelectric coefficient are also reinforced. In vitro and in vivo experiments, performed on arteries, of sensors based on these films demonstrated the high potential of the material to detect the strain of soft tissues and to function at biologic human frequencies

P(VDF-TrFE)

Plastifiant

Polarisation électrique

Structuration du polymère

Propriétés mécaniques

Capteurs biomédicaux

P(VDF-TrFE)

Plasticizer

Electric polarization

Polymer structure

Mechanical properties

Biomedical sensors

530.413

620.192

Herstellung und Charakterisierung pyroelektrischer P(VDF-TrFE)-Beschichtungen für Anti-Eis-Anwendungen

Apelt, Sabine

10 August 2021

Das unerwünschte Aufwachsen oder Anhaften von Eis an z.B. Windenergieanlagen und Wärmetauschern kann zum Funktionsverlust oder zur temporären Stilllegung der gesamten technischen Anlage führen. Bekannte Abwehrmechanismen sind das aktive Beheizen der Oberflächen oder der Einsatz von Enteisungschemikalien. Um den Verbrauch der hierfür benötigten elektrischen Energie oder Enteisungsmittel zu minimieren, werden in zunehmendem Maß passive Oberflächenbeschichtungen zur Gefrierverzögerung und Adhäsionsminimierung entwickelt. Der Einsatz pyroelektrischer Materialien bietet einen Lösungsansatz, der über bisher bekannte Abwehrstrategien hinausgeht. Es wird angenommen, dass pyroelektrisch generierte Oberflächenladungen während der Abkühlung entweder förderlich oder verzögernd auf die Eiskeimbildung wirken können. Dünne Schichten aus pyroelektrischem Poly-(Vinylidenfluorid - co - Trifluorethylen) haben wegen ihrer leichten Verarbeitbarkeit, hohen Flexibilität und pyroelektrischen Eigenschaften Interesse an ihrer Anwendung als funktionelle Beschichtung geweckt. Für eine industrielle Anwendung von P(VDF-TrFE) ist jedoch ein vertieftes Verständnis darüber erforderlich, wie sich der Beschichtungsprozess auf die resultierende Kristallinität, kristallographische Orientierung und Rauheit auswirkt. Die Morphologie teilkristalliner P(VDF-TrFE)-Beschichtungen wurde in dieser Arbeit in Abhängigkeit der Beschichtungsmethode, des Lösungsmittels, der Schichtdicke und der Wärmebehandlung mithilfe von Röntgenweitwinkelstreuung, Röntgenreflektometrie und Infrarot-Reflexions-Absorptions-Spektroskopie untersucht. Mit Hilfe von Rasterkraftmikroskopie- und Kontaktwinkel-Messungen wurden die resultierende Topographie und Rauheit der Schichten überprüft. Auf Grundlage der Ergebnisse dieser Messungen kann die dominierende edge-on Orientierung der P(VDF-TrFE)-Polymerketten entweder mit einem transkristallin-artigen Mechanismus oder Konfinement-Effekten erklärt werden. An den P(VDF-TrFE)-Dünnschichten wurde eine Vielzahl von Vereisungsexperimenten mit aufliegenden Wassertropfen durchgeführt, um den Einfluss der verschiedenen Schichtparameter wie Polarisierungsrichtung, Schichtdicke, verwendetes Lösungsmittel, Beschichtungstechnologie, Substrat und Wärmebehandlung auf die erreichbare Gefrierverzögerung unabhängig voneinander zu ermitteln. Die Rauheit der Schichten sowie substratspezifische Entnetzungserscheinungen veränderten hierbei signifikant die Verteilung der Gefriertemperaturen von Wassertropfen in Kontakt mit den P(VDF-TrFE)-Dünnschichten. Im Gegensatz dazu wurde kein signifikanter Einfluss der Dicke, Morphologie oder des pyroelektrischen Effekts auf die erreichbare Gefrierverzögerung gefunden. Es kann demnach geschlussfolgert werden, dass die heterogene Eiskeimbildung stärker durch lokale Rauheiten im nm-Bereich beeinflusst wird als durch integrale Eigenschaften wie beispielsweise Oberflächenladungen. Die Eisadhäsion auf P(VDF-TrFE) wird hauptsächlich durch Rauheiten im µm-Bereich, die Umgebungstemperatur und den Ionengehalt der flüssigen Phase bestimmt. Auch hier konnte kein signifikanter Einfluss geladener Oberflächen auf die Haftfestigkeit von Eis ausfindig gemacht werden. Statistische Tests ergaben, dass die Verteilung der Gefriertemperaturen unabhängiger Tropfen auf Oberflächen einem Spezialfall der Extremwertstatistik, der so genannten Gumbel-Verteilung, entspricht. Dies ermöglicht die Definition neuartiger Temperaturkennwerte für die Weiterentwicklung und Prüfung von Anti-Eis-Oberflächen.:Inhaltsverzeichnis 1. Einleitung und Motivation 2. Stand der Forschung 2.1. Pyroelektrika 2.1.1. Der pyroelektrische Effekt 2.1.2. Pyroelektrische Werkstoffe 2.1.3. Stabilität pyroelektrischer Materialien in wässrigen Medien 2.1.4. PVDF und P(VDF-TrFE) 2.2. Elektrochemische Doppelschicht 2.2.1. Aufbau und Modelle 2.2.2. Ursachen für Ladungen an Grenzflächen 2.2.3. Isoelektrischer Punkt und Ladungsnullpunkt 2.2.4. Orientierung von Wassermolekülen in der EDL 2.3. Vereisung 2.3.1. Wasser und Eis 2.3.2. Anti-Eis Strategien 2.3.3. Gefrierverzögerung 2.3.4. Eisadhäsion 2.4. Pyroelektrika in wässrigen Medien 2.4.1. Charakterisierungsmöglichkeiten 2.4.2. Anwendungsfelder 3. Materialien und Methoden 3.1. Materialien 3.2. Herstellung pyroelektrischer Beschichtungen 3.3. Schichtcharakterisierung 3.4. Vereisungsneigung 3.5. Statistische Methoden 4. Ergebnisse 4.1. Charakterisierung der P(VDF-TrFE) Beschichtungen 4.1.1. Schichtdicke (Ellipsometrie) und mechanische Eigenschaften 4.1.2. Morphologie (DSC, GIWAXS, XRR, IRRAS) 4.1.3. Elektrische Eigenschaften 4.1.4. Topographie (AFM und Kontaktwinkel) 4.2. Vereisungsneigung von P(VDF-TrFE) 4.2.1. Gefrierverzögerung 4.2.2. Eisadhäsion 4.3. Vergleichsmessungen auf poliertem Aluminium 4.3.1. Kontaktwinkel 4.3.2. Gefrierverzögerung 4.3.3. Eisadhäsion 5. Diskussion 5.1. Schichtherstellung, -charakterisierung und -eignung 5.1.1. Schichtdicke 5.1.2. Eignung der Charakterisierungsmethoden 5.1.3. Vergleich von Dip- und Spin-Coating 5.1.4. Eignung von P(VDF-TrFE) für Anti-Eis-Beschichtungen 5.2. Anti-Eis-Eigenschaften 5.2.1. Erreichbare Gefrierverzögerung 5.2.2. Eisadhäsion 6. Zusammenfassung und Ausblick Literaturverzeichnis Abbildungsverzeichnis Tabellenverzeichnis Symbol- und Abkürzungsverzeichnis Veröffentlichungen Anhang / Active de-icing of technical surfaces, such as for wind turbines and heat exchangers, currently requires the usage of heat or chemicals. Passive coating strategies that either postpone the freezing of covering water droplets or lower the ice adhesion strength would be beneficial in order to save costs and energy. One hypothesis is that pyroelectric active materials can either delay or promote heterogeneous ice nucleation because of the surface charges generated when these materials are subject to a temperature change. Pyroelectric poly-(vinylidene fluoride - co - trifluoroethylene) P(VDF-TrFE) thin films have created interest in their application because of their easy processibility, high flexibility and ferroelectric properties. The industrial application of P(VDF-TrFE) requires an understanding of the deposition process of films and in particular the resulting crystallinity, crystallographic orientation and roughness. In this work it has been proposed that an interface-mediated crystallization process occurs when P(VDF-TrFE) thin films are deposited from a solvent, resulting in a dominantly edge-on orientation caused either by a transcrystallinity mechanism or confinement effect. The morphology of the semi-crystalline thin film was studied as a function of the deposition method, solvent, film thickness and annealing temperature by grazing incidence wide-angle X-ray scattering, X-ray reflectometry and infrared reflection absorption spectroscopy. Atomic force microscopy measurements were used to examine the resulting topography and contact angle measurements to additionally verify the low roughness of the coatings. Freezing experiments with water droplets subjected to a cooling rate of 1K/min were made on P(VDF-TrFE) coatings in order to separate the effect of the different film parameters such as the poling direction, film thickness, used solvent, deposition process, underlying substrate and annealing temperature on the achievable supercooling. The topography and substrate-specific dewetting effects significantly changed the distribution of freezing temperatures of water droplets in contact with the P(VDF-TrFE) thin films. In contrast, no significant effect of the thickness, morphology or pyroelectric effect of the as-prepared domain-state on the freezing temperatures was found. Statistical tests revealed that the distribution of freezing temperatures of individual droplets deposited on surfaces match a special case of extreme-value statistics, the so-called Gumbel-distribution. This allows for the definition of novel parameters for the development and testing of anti-icing surfaces. The adhesion strength of ice to P(VDF-TrFE) is mainly determined by the topography, temperature and ion-content of the liquid phase. In contrast, surface charges do not significantly influence the ice adhesion strength.:Inhaltsverzeichnis 1. Einleitung und Motivation 2. Stand der Forschung 2.1. Pyroelektrika 2.1.1. Der pyroelektrische Effekt 2.1.2. Pyroelektrische Werkstoffe 2.1.3. Stabilität pyroelektrischer Materialien in wässrigen Medien 2.1.4. PVDF und P(VDF-TrFE) 2.2. Elektrochemische Doppelschicht 2.2.1. Aufbau und Modelle 2.2.2. Ursachen für Ladungen an Grenzflächen 2.2.3. Isoelektrischer Punkt und Ladungsnullpunkt 2.2.4. Orientierung von Wassermolekülen in der EDL 2.3. Vereisung 2.3.1. Wasser und Eis 2.3.2. Anti-Eis Strategien 2.3.3. Gefrierverzögerung 2.3.4. Eisadhäsion 2.4. Pyroelektrika in wässrigen Medien 2.4.1. Charakterisierungsmöglichkeiten 2.4.2. Anwendungsfelder 3. Materialien und Methoden 3.1. Materialien 3.2. Herstellung pyroelektrischer Beschichtungen 3.3. Schichtcharakterisierung 3.4. Vereisungsneigung 3.5. Statistische Methoden 4. Ergebnisse 4.1. Charakterisierung der P(VDF-TrFE) Beschichtungen 4.1.1. Schichtdicke (Ellipsometrie) und mechanische Eigenschaften 4.1.2. Morphologie (DSC, GIWAXS, XRR, IRRAS) 4.1.3. Elektrische Eigenschaften 4.1.4. Topographie (AFM und Kontaktwinkel) 4.2. Vereisungsneigung von P(VDF-TrFE) 4.2.1. Gefrierverzögerung 4.2.2. Eisadhäsion 4.3. Vergleichsmessungen auf poliertem Aluminium 4.3.1. Kontaktwinkel 4.3.2. Gefrierverzögerung 4.3.3. Eisadhäsion 5. Diskussion 5.1. Schichtherstellung, -charakterisierung und -eignung 5.1.1. Schichtdicke 5.1.2. Eignung der Charakterisierungsmethoden 5.1.3. Vergleich von Dip- und Spin-Coating 5.1.4. Eignung von P(VDF-TrFE) für Anti-Eis-Beschichtungen 5.2. Anti-Eis-Eigenschaften 5.2.1. Erreichbare Gefrierverzögerung 5.2.2. Eisadhäsion 6. Zusammenfassung und Ausblick Literaturverzeichnis Abbildungsverzeichnis Tabellenverzeichnis Symbol- und Abkürzungsverzeichnis Veröffentlichungen Anhang

info:eu-repo/classification/ddc/667

ddc:667

Poly(vinylidene fluoride-co-trifluoroethylene) Thin Films after Dip- and Spin-Coating

Apelt, Sabine, Höhne, Susanne, Mehner, Erik, Böhm, Carolin, Malanin, Mikhail, Eichhorn, Klaus-Jochen, Jehnichen, Dieter, Uhlmann, Petra, Bergmann, Ute

02 February 2024

The ferro-, pyro- and piezoelectric properties of poly(vinylidene fluoride-co-trifluoroethylene) P(VDF-TrFE) have created interest with regard to its application in aqueous and ambient surroundings for sensors, functional coatings, and in the field of life sciences. P(VDF-TrFE) thin films are usually applied via spin-coating, but dip-coating will be advantageous especially for irregularly shaped substrates. The morphology of dip- and spin-coated semi-crystalline thin films is studied as a function of both the film thickness and the annealing temperature. The characterization of the films is carried out by grazing incidence wide-angle X-ray scattering (GIWAXS), X-ray reflectometry (XRR), and infrared reflection absorption spectroscopy (IRRAS). Atomic force microscopy measurements (AFM) are used to examine the resulting topography. It is found that both spin- and dip-coated thin films crystallize in the desired edge-on orientation, but the overall crystallinity after dip-coating is decreased compared to the spin-coated films of comparable thickness and the resulting roughness is increased. The higher roughness is most probably caused by the slower evaporation of the solvents and a secondary crystallization process at the air-polymer interface.

info:eu-repo/classification/ddc/540

ddc:540