STRUCTURAL PHENOMENA OF MULTILAYERED POLYMERIC FILMS

Lai, Chuan-Yar

27 August 2012

No description available.

Polymers

multilayered

nanolayers

mechanical properties

interdiffusion

Blendas condutoras elétricas obtidas a partir do látex de seringueira Hevea Brasiliensis com polianilina / Electrical conductive blends obtained using the rubber tree Hevea brasiliensis latex with polyaniline

Teruya, Marcia Yumi

28 March 2003

É grande o interesse em combinar as propriedades mecânicas e elétricas de diferentes materiais poliméricos. Neste trabalho, filmes de Borracha Natural com camadas superficiais condutoras de polianilina (PANI) são preparados e caracterizados por diferentes técnicas. A PANI dopada foi depositada em ambos os lados do filme de borracha por polimerização química \"in situ\" da anilina a temperatura ambiente. O processo da polimerização da PANI \"in situ\" foi otimizado variando a concentração dos reagentes químicos com o objetivo de se obter uma camada de PANI com espessura desejada, boa adesão na borracha e que produzisse também aumento da condutividade elétrica na superfície. As amostras obtidas são caracterizadas usando-se Microscopia Eletrônica de Varredura, Microscopia Óptica, Difratometria de raios-X, análise por Calorimetria Diferencial de Varredura, análise Termo-Dinâmico-Mecânica, análise Termogravimétrica, Espectroscopia no FT-IR, Ensaio Mecânico e condutividade elétrica na superfície e no volume dos filmes preparados. Os resultados mostram que os filmes produzidos são do tipo multicamadas, pois não há uma interpenetração da PANI na borracha. A melhor condutividade e uniformidade é obtida com filmes preparados com três deposições, atingindo a ordem de 10-7 S/cm / The combination of properties of different polymeric materials in one sample is of great interest. In this work natural rubber films covered with a layer of conductive polyaniline (PANI) were prepared and studied by means of several experimental techniques. The doped PANI layer was deposited onto both rubber films surfaces by the \"in situ\" polymerization technique. The polymerization of PANI was performed at room temperature and the deposition process was optimized in order to obtain a PANI layer with an adequate thickness, good adhesion to the rubber and to promote the increase of its surface electric conductivity. Samples were characterized employing the scanning electron microscopy, optical microscopy, X-ray diffractometry, differential scanning calorimetry, thermo gravimetric analysis, dynamic mechanical thermal analysis, mechanical analysis and surface/volume electric conductivity. Results showed that the formed films consisted of a PANI layer that did not penetrated in the rubber. The better uniformity of deposition and maximum electric conductivity of the order of 10-7 S/cm was obtained on films that were prepared by deposition of three PANl layers

Borracha natural

Condutividade elétrica.

Electrical conductive

Nanocamadas

Nanolayers

Natural rubber

Polianilina

Polyaniline

Blendas condutoras elétricas obtidas a partir do látex de seringueira Hevea Brasiliensis com polianilina / Electrical conductive blends obtained using the rubber tree Hevea brasiliensis latex with polyaniline

Marcia Yumi Teruya

28 March 2003

É grande o interesse em combinar as propriedades mecânicas e elétricas de diferentes materiais poliméricos. Neste trabalho, filmes de Borracha Natural com camadas superficiais condutoras de polianilina (PANI) são preparados e caracterizados por diferentes técnicas. A PANI dopada foi depositada em ambos os lados do filme de borracha por polimerização química \"in situ\" da anilina a temperatura ambiente. O processo da polimerização da PANI \"in situ\" foi otimizado variando a concentração dos reagentes químicos com o objetivo de se obter uma camada de PANI com espessura desejada, boa adesão na borracha e que produzisse também aumento da condutividade elétrica na superfície. As amostras obtidas são caracterizadas usando-se Microscopia Eletrônica de Varredura, Microscopia Óptica, Difratometria de raios-X, análise por Calorimetria Diferencial de Varredura, análise Termo-Dinâmico-Mecânica, análise Termogravimétrica, Espectroscopia no FT-IR, Ensaio Mecânico e condutividade elétrica na superfície e no volume dos filmes preparados. Os resultados mostram que os filmes produzidos são do tipo multicamadas, pois não há uma interpenetração da PANI na borracha. A melhor condutividade e uniformidade é obtida com filmes preparados com três deposições, atingindo a ordem de 10-7 S/cm / The combination of properties of different polymeric materials in one sample is of great interest. In this work natural rubber films covered with a layer of conductive polyaniline (PANI) were prepared and studied by means of several experimental techniques. The doped PANI layer was deposited onto both rubber films surfaces by the \"in situ\" polymerization technique. The polymerization of PANI was performed at room temperature and the deposition process was optimized in order to obtain a PANI layer with an adequate thickness, good adhesion to the rubber and to promote the increase of its surface electric conductivity. Samples were characterized employing the scanning electron microscopy, optical microscopy, X-ray diffractometry, differential scanning calorimetry, thermo gravimetric analysis, dynamic mechanical thermal analysis, mechanical analysis and surface/volume electric conductivity. Results showed that the formed films consisted of a PANI layer that did not penetrated in the rubber. The better uniformity of deposition and maximum electric conductivity of the order of 10-7 S/cm was obtained on films that were prepared by deposition of three PANl layers

Borracha natural

Condutividade elétrica.

Nanocamadas

Polianilina

Electrical conductive

Nanolayers

Natural rubber

Polyaniline

GRADIENT MUTILAYERED FILMS AND CONFINED CRYSTALLIZATION OF POLYMER NANOLAYERS BY FORCED ASSEMBLY COEXTRUSION

Ponting, Michael T.

17 May 2010

No description available.

Chemical Engineering

Multilayer Coextrusion

Nanolayers

Oxygen Permeability

Gradient Layers

Photonic Crystals

Crystallization

Foaming

Delamination

Mechanical Failure

Adsorption and Grafting of Polyelectrolytes at Solid-Liquid Interfaces

Houbenov, Nikolay

06 August 2005

A novel strategy for fabrication of responsive functional polymer films is based on grafting of several different functional polymers onto a solid substrate at high grafting density, resulting in varied types of polymer brushes. Such an arrangement suggests many interesting applications of the multicomponent polymer brushes, regarding their versatile adaptive surfaces, capable for responding to changes of solvent polarity, pH, temperature, electromagnetic field and other stimuli, generally by reversible swelling. Mixed amphiphilic polystyrene-poly(2-vynil pyridine) (PS-P2VP) brushes are an example for responsive class of smart materials, which can switch between hydrophilic and hydrophobic energetic state upon changes in the quality of surrounding media. The switching of wettability was found to operate in a broad range and was selectively controlled in organic solvents and in aqueous solutions. Another example for an adaptive/switching behavior is addressed to a polymer brush with a remarkable response to the pH and the ionic strength variations of the aqueous solutions. Combination of weak polyacrylic acid, PAA, and weak polybase, P2VP, in the anchored layer allowed one with a small shift of the pH, to obtain a significant effect on the surface and the interfacial properties of the material. Both type of polymer brushes were examined as adsorbing materials for nanoparticles and charged synthetic- and bio-macromolecules. Their adaptive properties were successively linked to the results of the adsorption experiments. The simplest case was adsorption of nano-particles, functionalised with strong ionic groups, onto binary, PAA-P2VP, polyelectrolyte brushes. Maintaining a constant charge density of the adsorbing component (strong polyelectrolyte effect), allowed one to cause and manipulate a privileged swelling of one of the weak polyelectrolyte brush layers, without affecting the adsorbate properties, and to regulate the thickness of adsorbed layer only by the pH signal. In the case of adsorption of macromolecules with tuneable electrical charge (polyampholytes and proteins), the system became more complicated, regarding their environmentally responsive properties, similar to that exhibited by the polymer brushes. The driving forces were regulated by the switching performance of the brush, simply by adjusting the pH and/or ionic strength conditions. The adsorbed amount and morphological changes of polyampholyte layers were investigated as function of pH and was performed on mixed amphiphilic and binary polyelectrolyte brushes. A special emphasis was set on the binary brush capability to take the control over the interfacial performance of attaching proteins. It was found, that the sharp environmental response of the adsorbent (the polymer brush) strongly influences the morphology of adsorbed protein layers, their thickness and properties. Changing the polarity of the substrate allowed one to regulate the adsorption processes qualitatively and quantitatively. The significant aggregation of protein molecules on PS-P2VP brush and their disassembly on PAA-P2VP brush at the same solvent conditions, we devote to the hydrophobic-hydrophilic transition, occurred at the surface by replacing PS with PAA. The protein aggregates, monitored on the surface of PS-P2VP, sufficiently decrease their size, when switching the brush energetic state from hydrophobic to hydrophilic by adjusting the pH of the media. This effect was found to be well controlled by the brush switching phenomenon in hydrophilic-hydrophobic direction and vice versa. In conclusion, we showed how the structural reorganization in thin polymer brush layers of different type may dramatically affect their surface properties. The adaptive behavior in response of external stimuli was found to be a basis for highly specific interactions, depending on geometric factors, conformational state and environment.

Polyelektrolytbürsten

schaltbare nano Schichten

polyelectrolyte brushes

switchable nanolayers

ddc:540

rvk:VE 6357

Bürstenpolymere

Dünne Schicht

Polyelektrolyt

Polymerfilm

Adsorption and Grafting of Polyelectrolytes at Solid-Liquid Interfaces

Houbenov, Nikolay

29 August 2005

A novel strategy for fabrication of responsive functional polymer films is based on grafting of several different functional polymers onto a solid substrate at high grafting density, resulting in varied types of polymer brushes. Such an arrangement suggests many interesting applications of the multicomponent polymer brushes, regarding their versatile adaptive surfaces, capable for responding to changes of solvent polarity, pH, temperature, electromagnetic field and other stimuli, generally by reversible swelling. Mixed amphiphilic polystyrene-poly(2-vynil pyridine) (PS-P2VP) brushes are an example for responsive class of smart materials, which can switch between hydrophilic and hydrophobic energetic state upon changes in the quality of surrounding media. The switching of wettability was found to operate in a broad range and was selectively controlled in organic solvents and in aqueous solutions. Another example for an adaptive/switching behavior is addressed to a polymer brush with a remarkable response to the pH and the ionic strength variations of the aqueous solutions. Combination of weak polyacrylic acid, PAA, and weak polybase, P2VP, in the anchored layer allowed one with a small shift of the pH, to obtain a significant effect on the surface and the interfacial properties of the material. Both type of polymer brushes were examined as adsorbing materials for nanoparticles and charged synthetic- and bio-macromolecules. Their adaptive properties were successively linked to the results of the adsorption experiments. The simplest case was adsorption of nano-particles, functionalised with strong ionic groups, onto binary, PAA-P2VP, polyelectrolyte brushes. Maintaining a constant charge density of the adsorbing component (strong polyelectrolyte effect), allowed one to cause and manipulate a privileged swelling of one of the weak polyelectrolyte brush layers, without affecting the adsorbate properties, and to regulate the thickness of adsorbed layer only by the pH signal. In the case of adsorption of macromolecules with tuneable electrical charge (polyampholytes and proteins), the system became more complicated, regarding their environmentally responsive properties, similar to that exhibited by the polymer brushes. The driving forces were regulated by the switching performance of the brush, simply by adjusting the pH and/or ionic strength conditions. The adsorbed amount and morphological changes of polyampholyte layers were investigated as function of pH and was performed on mixed amphiphilic and binary polyelectrolyte brushes. A special emphasis was set on the binary brush capability to take the control over the interfacial performance of attaching proteins. It was found, that the sharp environmental response of the adsorbent (the polymer brush) strongly influences the morphology of adsorbed protein layers, their thickness and properties. Changing the polarity of the substrate allowed one to regulate the adsorption processes qualitatively and quantitatively. The significant aggregation of protein molecules on PS-P2VP brush and their disassembly on PAA-P2VP brush at the same solvent conditions, we devote to the hydrophobic-hydrophilic transition, occurred at the surface by replacing PS with PAA. The protein aggregates, monitored on the surface of PS-P2VP, sufficiently decrease their size, when switching the brush energetic state from hydrophobic to hydrophilic by adjusting the pH of the media. This effect was found to be well controlled by the brush switching phenomenon in hydrophilic-hydrophobic direction and vice versa. In conclusion, we showed how the structural reorganization in thin polymer brush layers of different type may dramatically affect their surface properties. The adaptive behavior in response of external stimuli was found to be a basis for highly specific interactions, depending on geometric factors, conformational state and environment.

info:eu-repo/classification/ddc/540

ddc:540

SYNTHESIS AND CHARACTERIZATION OF ELASTOMER-BASED COMPOSITES AND POLYMER-IMMOBILIZED COLLOIDAL TRANSITION METAL NANOPARTICLES: CATALYTIC SELECTIVITY AND MORPHOLOGY

VU, YEN THI

08 November 2001

No description available.

Chemistry, Polymer

clay, montmorillonite, nanolayers

polypropylene, thermoplastic elastomers

palladium nanoparticles, catalyst

Deposição de nano-camadas de VO2 por Magnetron Sputtering / Deposition of VO2 Nanolayers by Magnetron Sputtering

Santos, Claudiosir Roque dos

13 April 2007

The vanadium dioxide (VO2) shows a metal-insulator transition (MIT) near the room temperature with huge changes in its electrical and optical behavior. Both the electrical and optic properties, and even the transition temperature, depend on the morphologic characteristics of the metal. In this work, vanadium oxide nanolayers were deposited onto glass substrate by reactive magnetron sputtering. The aim was to obtain the best deposition parameters, like substrate temperature (Ts) and oxygen partial pressure (PO2), for the VO2M1 phase synthesis. Samples deposited with oxygen partial pressures ranging from 10 to 20% of the total pressure, and Ts=400°C, have shown metal insulator transition when submitted to a 550°C ex-situ thermal treatment. The analysis of the x-ray diffraction spectra has shown that all the samples were formed simultaneously by more than one phase of vanadium oxides. Moreover, we identify a reciprocal correspondence between the 2q = 27,8° peak, corresponding to (011) plan in VO2M1, and the MIT transition. The measured resistance in samples with VO2M1, in the temperature range of 25 to 100°C, showed variations of almost three orders of magnitude. The transition critical temperature took place between 59 and 82°C and the hysteresis loops width ranged between 9 and 13°C / O dióxido de Vanádio (VO2) apresenta uma transição metal isolante (MIT) próxima da temperatura ambiente com uma grande variação em suas propriedades elétricas e ópticas. Tanto as propriedades elétricas e ópticas quanto a própria temperatura de transição dependem das características morfológicas do material. Neste trabalho, nano-camadas de óxido de Vanádio foram produzidas sobre substratos de vidro pela técnica de magnetron sputtering reativo, visando determinar os parâmetros de deposição, em especial a temperatura do substrato (Ts) e pressão parcial de Oxigênio (PO2), adequadas para a obtenção da fase VO2M1. Amostras depositadas com pressões parciais de Oxigênio entre 10 e 20% da pressão total e Ts=400°C apresentaram MIT quando submetidas a tratamentos térmicos ex-situ a 550°C. A análise dos espectros de difração de raios-x mostrou que houve formação de mais de uma fase simultaneamente em todas as amostras, no entanto há uma correspondência recíproca entre o pico de difração de raios-x em 2q = 27,8° , correspondente ao plano (011) do VO2M1, e a transição MIT na resistividade. As medidas de resistência em função da temperatura, realizadas entre 25 e 100°C, mostraram, nas amostras com VO2M1, transição com variação na resistência em até três ordens de grandeza com temperaturas críticas entre 59 e 82°C e curvas de histerese com larguras entre 9 e 13°C

Nano-camadas deVO2

Magnetron sputtering

Transição metal-isolante

VO2

Magnetron sputtering

Metal-insulator transition

VO2 nanolayers

CNPQ::CIENCIAS EXATAS E DA TERRA::FISICA