The effects of polymer microstructure and macrostructure on SBR/polybutadiene blend miscibility, phase morphology, and cured rubber properties

Maier, Thomas Robert

January 1995

No description available.

Plastics Technology

SBR/polybutadiene blend

Morphology

Cured rubber

Noves aproximacions a la síntesi i caracterització de poliglicols al·lílics, polihidrosiloxans i surfactants copolimèrics. Avaluació d'aquests surfactants en formulacions de poliuretà

Nadal i Soy, Josep

10 December 2002

Els polímers són una sèrie de compostos que troben un ampli ventall d'aplicacions en la indústria actual. Un exemple són les espumes de poliuretà, estructures de tipus cel·lular obtingudes mitjançant la reacció química entre compostos de tipus isocianat i compostos de tipus poliol (polièters amb diferent nombre de grups hidroxil). És imprescindible l'ús d'additius d'estructura tensioactiva (surfactants de silicona) per estabilitzar el procés d'espumació i per proporcionar una estructura cel·lular ordenada i homogènia en mida i distribució. La síntesis i caracterització de les molècules precursores (polihidrosiloxans i polièters al·lílics), l'estudi de la reacció d'hidrosililació com a via d'obtenció dels diferents surfactants per reacció d'addició entre els polihidrosiloxans i els polièters al·lílics i la caracterització i avaluació en formulacions comercials de poliuretà dels surfactants sintetitzats han constituït els objectius del present treball.MEMÒRIALa Tesi Doctoral ha estat presentada seguint el següent esquema:CAPÍTOL I. INTRODUCCIÓ A LA QUÍMICA DEL POLIURETÀ.Es presenten els principis de la química del poliuretà, fent esment dels recents avenços en la síntesis i caracterització d'aquests compostos polimèrics, així com un apartat concret centrat en els surfactants de silicona. Es presenten les estructures habituals d'aquests compostos comercials i es detallen les reaccions de síntesi i les característiques físiques que aquests compostos proporcionen a les espumes de poliuretà.CAPÍTOL II. OBJECTIUS.1.- Síntesis y caracterització d'una àmplia gamma de poliglicols al·lílics i de polihidrosiloxans amb grups hidrur reactius, ambdós precursors d'estructures polimèriques de tipus surfactant.2.- Estudi de la reacció d'hidrosililació com a via de formació d'enllaços Si-C no hidrolitzables, mitjançant la reacció d'addició entre els substrats al·lílics insaturats i els polisiloxans amb grups hidrur reactius.3.- Caracterització de les estructures polimèriques de tipus surfactant sintetitzades i avaluació d'aquestes en formulacions de poliuretà, a fi de relacionar l'estructura química d'aquests oligómers amb els efectes físics que originen en l'espuma de poliuretà.CAPÍTOL III. SÍNTESI I CARACTERITZACIÓ DE SUBSTRATS AL·LÍLICS INSATURATS DE TIPUS POLIGLICOL.S'han caracteritzat per HPLC-UV una sèrie de polietilenglicols comercials. S'ha estudiat la reacció de derivatització al·lílica sobre els grups hidroxil dels polièters comercials (PEG, PPG i copolímers PEG-PPG) i s'han caracteritzat exhaustivament els productes sintetitzats (1H,13C-RMN, GC, GC-MS, FTIR, ESI-MS, HPLC-UV). S'ha iniciat un estudi de polimerització aniònica sobre nous epòxids amb un punt de diversitat molecular, sintetitzant-se i caracteritzant-se els corresponents nous polièters obtinguts. CAPÍTOL IV. SÍNTESI I CARACTERITZACIÓ DE POLIHIDROSILOXANS REACTIUS.S'estudia la síntesis de polihidrosiloxans amb grups hidrur reactius, mitjançant la reacció de polimerització aniònica d'obertura d'anell ("AROP, anionic ring opening polimerization") i mitjançant la reacció de polimerització per equilibració catiònica. Es presenta una caracterització exhaustiva dels productes sintetitzats i es descriu la naturalesa de la microestructura polimèrica a partir de la distribució bivariant dels copolímers PDMS-co-PHMS (poli(dimetilsiloxà)-co-poli(hidrometilsiloxà)).CAPÍTOL V. ESTUDI SISTEMÀTIC DE LA REACCIÓ D'HIDROSILILACIÓ.S'ha estudiat la reacció d'hidrosililació amb la finalitat de sintetitzar estructures copolimèriques poliglicol-polisiloxà a partir de la reacció de polisiloxans hidrur reactius i polièters al·lílics. S'han provat diferents catalitzadors (Pt/C 5%, cat. de Speier i cat. de Karstedt), s'han sintetitzat diferents estructures tensoactives (lineals i ramificades) i s'ha modelitzat les diferents reaccions secundàries observades, per presentar un estudi mecanístic de la reacció d'hidrosililació aplicada a la síntesis de molècules d'elevat PM a partir de la reacció entre substrats al·lílics insaturats i polihidrosiloxans.CAPÍTOL VI. AVALUACIÓ DELS SURFACTANTS EN FORMULACIONS DE POLIURETÀ.S'ha estudiat la idoneïtat dels surfactants de silicona sintetitzats en diferents formulacions de poliuretà comercials. S'ha relacionat el comportament físic d'aquests surfactants en les espumes de poliuretà amb la seva estructura química a partir de l'anàlisi per microscòpia electrònica de rastreig.CAPÍTOL VII. CONCLUSIONS.S'han esposat les conclusions extretes de cada capítol. / The present review has been structured in three parts, firstly a general introduction to polyurethane chemistry and the specific role that silicone surfactants develop, secondly a memory that contents a concise description of the PhD Thesis structure and finally the presentation of the results obtained and their discussion.1.- INTRODUCTIONPolyurethane is one of the most important polymers used in the industry worldwide. The reaction, discovered in 1937 by Otto Bayer, consists in a polyaddition reaction between hydroxyl compounds and isocyanate groups. This reaction forms the new urethane group (strictly a carbamat group) that provide the chemical structure of the polymer. In the presence of different amounts of water, another reaction is involved, between isocyanate groups and water, in order to obtain urea groups. This reaction is very important because, besides generates new polyurea structures it generates carbon dioxide (CO2), the blowing aggent mostly used in the formulations of polyurethane.Actually, a lot of applications of polyurethane products take advantage on the specific cellular structure that presents, specially flexible foams in mattresses, sofas, seats, rigid foams as insulation panels and semi-rigid foams in the automotive industry. The cellular structure is obtained in the foaming process of the reaction, which involves the generation of a gas (usually CO2 although other compounds like pentane, HCFC's and external CO2 had been used) and the growing of the cell because of the exothermic process. The foaming process is usually an unstable state that needs the participation of a surfactant, a silicone structure that provides the necessary stabilizing capacity in the foaming process. Moreover, another important feature of silicone surfactants is to improve the order and distribution of the cells in the foam.Generally, the chemical structure of silicone surfactants is co polymeric, consisting in an hydrophobic part composed by the polysiloxane group and an hydrophilic part, usually being made up of different types of polyether structures. This different physical behaviour in the same molecule provides the specific characteristics of silicone surfactants. In order to obtain commercially available surfactants, it has been necessary to study the synthesis and the characterization of the components in the surfactant molecule (the polyether and the polysiloxane groups) and to perform a study of the hydrosilylation, the chemical reaction that generates the co polymeric structure by the reaction between the polyether and the polysiloxane constituents.2.- PhD THESIS STRUCTUREThe thesis has been organized in seven chapters, being the first of them the introduction to polyurethane chemistry. In the second chapter are exposed the aims of the work. The third chapter is the synthesis and characterization of polyether type unsaturated substrates, the fourth is the synthesis and characterization of reactive polyhydrosiloxanes and the fifth is the systematic study on the hydrosilylation reaction. The evaluation of surfactants in different polyurethane formulations is described in the sixth chapter whereas the concluding remarks have been reported in the seventh chapter.3.- RESULTS AND DISCUSSIONThe first part of this study details the synthesis and characterization of unsaturated polyethers, substrates of the hydrosilylation reaction. Thus, the allylic modification of commercial monohidroxy polyethers has allowed the synthesis of this unsaturated substrates that can react through hydrosilylation reaction with Si-H bonds. In order to obtain new polyether structures, an investigation about the anionic polymerisation of new epoxies has been developed. These new polyether structures have been extensively characterized to estimate the polymerization degree and their molecular weight.The synthesis and characterization of reactive polysiloxane compounds (containing Si-H bonds in their structure) has been the second aim of this work. In order to obtain these polysiloxane structures, both anionic polymerization of cyclic trisiloxane compounds and cationic polymerization have been studied. Its interesting to emphasize that the results have shown that the microstructure of the copolymeric poly(dimethylsiloxane)-co-poly(hidromethylsiloxane) is statistical in the monomeric distribution (based on MALDI-TOF-MS and 29Si-RMN results), thus the chemical composition along the polymer chain become constant.Little information has been reported in the literature about the hydrosilylation as source of polymer structures. In order to clarify the synthetic behaviour of the reaction between polysiloxanes with Si-H bonds and allylic polyethers, an exhaustive study of the hydrosilylation as been developed. Different catalysts (Speier's, Karstedt's and an heterogeneous Pt/C 5% have been studied), concluding that the Karstedt catalyst has given the better behaviour.Finally, the evaluation of the surfactant structures synthesized in different commercially available polyurethane formulations as allowed obtaining a relation between the chemical structure of the silicone surfactant and the physical behavior in the foaming process. SEM has been the technique of choice to better characterize the otained foams.

Polymer microstructures

Microestructura polímer

Reacció d'hidrosililació

Polimerización catiónica

Polimerització catiònica

Reacción de hidrosililación

Polimerización aniónica

Anionic polymerisation

Cationic polymerization

Polimerització aniònica

Polyurethane

Hydrosilylation reaction

Poliuretano

Poliuretà

546

67

Studies On Conducting Polymer Microstructures : Electrochemical Supercapacitors, Sensors And Actuators

Pavan Kumar, K

07 1900

With the discovery of conductivity in doped polyacetylene (PA), a new era in synthetic metals has emerged by breaking the traditionally accepted view that polymers were always insulating. Conducting polymers are essentially characterized by the presence of conjugated bonding on the polymeric back bone, which facilitates the formation of polarons and bipolarons as charge carriers. Among the numerous conducting polymers synthesized to date, polypyrrole (PPy) is by far the most extensively studied because of prodigious number of applications owing to its facile polymerizability, environmental stability, high electrical conductivity, biocompatibility, and redox state dependent physico-chemical properties. Electrochemically prepared PPy is more interesting than the chemically prepared polymer because it adheres to the electrode surface and can be directly used for applications such as supercapacitors, electrochemical sensors, electromechanical actuators and drug delivery systems. In quest for improvement in quality of the device performances in the mentioned applications, micro and nano structured polymeric materials which bring in large surface area are studied. Finding a simple and efficient method of synthesis is very important for producing devices of PPy microstructures. Till date, Hard and soft template methods are the most employed methods for synthesis of these structures. Soft template based electrochemical methods are better than hard template methods to grow clean PPy microstructures on electrode substrates as procedures for removal of hard templates after the growth of microstructures are very complex. As per the literature, there is no unique method available to grow PPy microstructures which can demonstrate several applications. Although gas bubble based soft template methods are exploited to grow conducting polymer microstructures of sizes in few hundreds of micrometers, studies on applications of the same are limited. Hence it is planned to develop procedures to grow microstructures that can be used in several applications. In the current work, PPy microstructures with high coverage densities are synthesized on various electrode substrates by soft template based electrochemical techniques. Hollow, hemispherical and spherical PPy microstructures are developed by a two step method using electro generated hydrogen bubble templates on SS 304 electrodes. In the first step, Hydrogen bubbles are electro generated and stabilized on the electrode in the presence of β- naphthalene sulfonic acid (β-NSA). In the second step, Pyrrole is oxidised over the bubble template to form PPy microstructures. Microstructures (open and closed cups) of average size 15 μm are uniformly spread on the surface with a coverage density of 2.5×105 units /cm2. Globular PPy microstructures are developed by a single step method using concomitantly electro generated oxygen bubble templates on SS 304 electrodes during electropolymerization. Microstructures of average size 4 μm are uniformly spread on the surface with a coverage density of 7×105 units/cm2. Surfactant properties of Zwitterionic 4-(2-hydroxyethyl)-1-piperazine ethane sulfonic acid (HEPES) are exploited for the first time to grow conducting polymer microstructures. Ramekin shaped PPy microstructures are developed using HEPES as the surfactant to stabilize hydrogen bubble templates in a two step electrochemical synthesis method. Microramekins of size 100 µm are uniformly spread on the surface with a coverage density of 3000 units/cm2. Micropipettes and microhorns of PPy are synthesised by a single step electrochemical route using HEPES as a surfactant. Hollow micropipettes of length 7 µm with an opening of 200 nm at the top of the structure are observed. Similarly microhorn/celia structures are observed with length 10-15 µm. Microcelia are uniformly distributed over the surface with each structure having a diameter of 2 µm at the base to 150 nm at the tip. Growth mechanism based on contact angle of the reactant solution droplets on the substrate is proposed. PPy microstructures are characterized by scanning electron microscopy, X-Ray photoelectron spectroscopy, Fourier transform infrared spectroscopy, Raman Spectroscopy and UV-Visible spectroscopy to study morphology, ‘chemical bonding and structure’ , ‘defects and charge carriers’. Applicability of the electrodes with PPy microstructures in supercapacitors is investigated by cyclic voltammetry, chronopotentiometry and electrical impedance spectroscopy. Electrodes developed by all the above methods demonstrated very good supercapacitance properties. Supercapacitor studies revealed very high specific capacitances (580, 915, 728 and 922 F/g,) and specific powers (20, 25, 13.89 and 15.91 kW/kg) for electrodes with PPy microstructures (H2 bubble based two step method, O2 bubble based single step method, HEPES stabilized H2 bubbble method and HEPES based microhorn/celia structures respectively). Supercapacitive behavior of all the electrodes is retained even after an extended charge-discharge cycling in excess of 1500 cycles. Horseradish peroxidase entrapped, bowl shaped PPy microstructures are developed for H2O2 biosensing. Amperometric biosensor has a performance comparable to the sensors reported in the literature with high sensitivity value of 12.8 μA/(cm2.mM) in the range 1.0 mM to 10 mM. Glucose oxidase entrapped PPy amperometric biosensor is developed for Glucose sensing. Sensitivity of 1.29 mA/(cm2.mM) is observed for β-D-Glucose sensing in the 0.1 mM to 5.0 mM range while 58 μA/(cm2.mM) is observed in the 5.0 to 40 mM range. Potentiometric urea sensor with urease entrapped PPy microstructures on SS electrode is developed. It is able to sense urea in the micromolar ranges down to 0.1 μM. It represented an excellent performance with sensitivity of 27 mV/decade. Sensitivity in the micromolar range is 4.9 mV/(μM.cm2). Drug encapsulation and delivery is successfully demonstrated by two actuation means (i) by electrochemical actuation, (ii) by actuation based on pH changes. Concepts are proved by delivering a fluorescent dye into neutral and acidic solutions. Drug delivery is confirmed by UV-Visible spectroscopy and Fluorescence microscopy. Finally, Micro/nanostructures with Tangerine, Hollow globular (Pani Poori), Chip, Flake, Rose, Worm, Horn and Celia shapes are synthesized electrochemically and scanning electron microscopic studies are presented. Controlled growth of microstructures on lithographically patterned gold interdigital electrodes is demonstrated with a future goal of creating addressable microstructures. The studies reported in the thesis provide an insight on various applications of PPy microstructures (supercapacitors, sensors and drug delivery systems) developed by a unique methodology based on electrochemically generated gas bubble templates.

Polymers

Polypyrrole Microstructures

Conducting Polymer Microstructures

Polypyrrole Nanostructures

Polypyrrole-Horseradish Peroxidase

Polypyrrole Microstructures - Synthesis

Electrochemical Supercapacitors

Electrochemical Sensors

Electrochemical Actuators

Conjugated Polymers

PPy Film

Theoretical Chemsistry