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Copolimerização de estireno e VeoVa 10: determinação das razões de reatividade e estudo do processo de polimerização em emulsão. / Copolymerization of styrene and VeoVa 10: determination of the reactivity ratios and study of the emulsion polymerization process.Barbosa, Natalia Bahia 06 July 2018 (has links)
Neste trabalho foram determinadas as razões de reatividade para a copolimerização entre estireno e VeoVa-10 através de estudo experimental de copolimerização em solução em tolueno. Os parâmetros foram obtidos através do ajuste aos dados experimentais dos modelos de Mayo-Lewis e Meyer-Lowry, utilizando o critério dos erros-nas-variáveis (método dos mínimos quadrados não-linear que considera a existência de erros em todas as variáveis medidas). A metodologia experimental desenvolvida, de polimerização em solução em ampolas preparadas dentro de uma glove box e submetidas a temperatura de 80°C, resultou em baixa conversão dos monômeros, adequada para a estimação das razões de reatividade pelos modelos. As amostras foram analisadas quantitativamente por espectroscopia de infravermelho para determinar, ao longo da reação, a conversão e as frações molares de cada um dos monômeros na mistura, sendo a composição do copolímero obtida pelo consumo dos monômeros. Foram obtidos valores de razões de reatividade bastante diferentes (restireno = 49.926 e rVeoVa10 = 1,062), evidenciando que a copolimerização destes monômeros em batelada leva a grandes desvios de composição, com tendência à formação de dois homopolímeros. O mesmo sistema de copolimerização foi também estudado no processo de polimerização em emulsão, em processos batelada alimentada e batelada intermitente. A conversão global dos monômeros e a distribuição de diâmetro médio das partículas foram analisadas durante a reação através das amostras coletadas ao longo do processo. Os efeitos das estratégias de alimentação avaliados foram apenas preliminares, pois não apresentaram resultados conclusivos. / In this work the reactivity ratios for the copolymerization between styrene and VeoVa-10 were determined through an experimental study of solution copolymerization in toluen. The parameters were obtained by fitting the experimental data with the Mayo-Lewis and Meyer-Lowry models using the error-in-variables criterion (non-linear least squares method that considers the existence of errors in all measured variables). The experimental methodology developed, solution polymerization in ampoules prepared in a glove box and reacted at 80 °C, resulted in low conversion of the monomers, suitable for estimation of the reactivity ratios by the models employed. The samples were analyzed quantitatively by infrared spectroscopy to determine, during the reaction, the conversion and the mole fractions of each monomer in the mixture, the composition of the copolymer being obtained by the consumption of the monomers. Very different reactivity ratios were obtained (rstyrene = 49.926 and rVeoVa10 = 1.062), showing that the batch copolymerization of these monomers leads to large composition drift, with a tendency to form two homopolymers. The same copolymerization system was also tested in emulsion polymerization process, in semi-continuous and intermittent batch modes. The overall conversion of the monomers and the mean particle diameter distribution were analyzed during the reaction through the samples collected throughout the process. The effects of the feeding strategies evaluated were only preliminary, as they did not present conclusive results.
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Photopolymerizations of multicomponent epoxide and acrylate/epoxide hybrid systems for controlled kinetics and enhanced material propertiesEom, Ho Seop 01 May 2011 (has links)
Cationic photopolymerization of multifunctional epoxides is very useful for efficient cure at room temperature and has been widely used in coatings and adhesives. Despite excellent properties of the final cured polymers, cationic photopolymerizations of epoxides have seen limited application due to slow reactions (relative to acrylates) and brittleness associated with a highly crosslinked, rigid network. To address these issues, two reaction systems were studied in this thesis: photoinitiated cationic copolymerizations of a cycloaliphatic diepoxide with epoxidized elastomers and acrylate/epoxide hybrid photopolymerizations. Oligomer/monomer structures, viscosity, compositions, and photoinitiator system were hypothesized to play important roles in controlling photopolymerizations of the epoxide-based mixtures. A fundamental understanding of the interplay between these variables for the chosen systems will provide comprehensive guidelines for the future development of photopolymerization systems comparable to the epoxide-based mixtures in this research.
For diepoxide/oligomer mixtures, the observed overall enhancement in polymerization rate and ultimate conversion of the cycloaliphatic diepoxide was attributed to the activated monomer mechanism associated with hydroxyl terminal groups in the epoxidized oligomers. This enhancement increased with increasing oligomer content. The mixture viscosity influenced the initial reactivity of the diepoxide for oligomer content above 50 wt.%. Real-time consumption of internal epoxides in the oligomers was successfully determined using Raman spectroscopy. Initial reactivity and ultimate conversion of the internal epoxides decreased with increasing the diepoxide content. This trend was more pronounced for the oligomer containing low internal epoxide content. These results indicate that the reactivity of the hydroxyl groups is higher toward cationic active centers of the diepoxide than those of the internal epoxides in the oligomers. These conclusions are consistent with physical property results. The enhanced fracture toughness and impact resistance were attributed to multimodal network chain-length distribution of copolymers containing the oligomer content between 70% and 80%.
For acrylate/epoxide hybrid mixtures, diacrylate oligomers significantly suppressed reactivities of cycloaliphatic mono/diepoxides, which was attributed to high mixture viscosity and highly crosslinked acrylate network. In this case, the dual photoinitiator system did not favor the epoxide reaction. Depending on the monovinyl acrylate secondary functionalities, enhanced reactivity and ultimate conversion of the diepoxide were attributed to a combined effect of a reduced viscosity and the radical-promoted cationic polymerization associated with the dual photoinitiator. The retarded and inhibited diepoxide reactivities with ether and urethane secondary groups were attributed to solvation and nucleophilicity/basicity effects, respectively. The influence of the diepoxide on the acrylate reactivity was attributed to dilution and polarity effects. In this case, high concentration of the free-radical photoinitiator is required for the dual photoinitiator system. Physical properties of hybrid polymers also varied with acrylate structures and monomer composition. Dynamic modulation methods were proposed to enhance the diepoxide reactivity and final properties in the presence of urethane acrylates.
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Neue Ansätze zur Monomersequenzkontrolle in synthetischen Polymeren / New approaches for monomer sequence control in synthetic polymersPfeifer, Sebastian January 2011 (has links)
Von der Natur geschaffene Polymere faszinieren Polymerforscher durch ihre spezielle auf eine bestimmte Aufgabe ausgerichtete Funktionalität. Diese ergibt sich aus ihrer Bausteinabfolge uber die Ausbildung von Uberstrukturen. Dazu zählen zum Beispiel Proteine (Eiweiße), aus deren Gestalt sich wichtige Eigenschaften ergeben. Diese Struktureigenschaftsbeziehung gilt ebenso für funktionelle synthetische Makromoleküle. Demzufolge kann die Kontrolle der Monomersequenz in Polymeren bedeutend für die resultierende Form des Polymermoleküls sein.
Obwohl die Synthese von synthetischen Polymeren mit der Komplexität und der Größe von Proteinen in absehbarer Zeit wahrscheinlich nicht gelingen wird, können wir von der Natur lernen, um neuartige Polymermaterialien mit definierten Strukturen (Sequenzen) zu synthetisieren. Deshalb ist die Entwicklung neuer und besserer Techniken zur Strukturkontrolle von großem Interesse für die Synthese von Makromolekülen, die perfekt auf ihre Funktion zugeschnitten sind.
Im Gegensatz zu der Anzahl fortgeschrittener Synthesestrategien zum Design aus- gefallener Polymerarchitekturen – wie zum Beispiel Sterne oder baumartige Polymere (Dendrimere) – gibt es vergleichsweise wenig Ansätze zur echten Sequenzkontrolle in synthetischen Polymeren. Diese Arbeit stellt zwei unterschiedliche Techniken vor, mit denen die Monomersequenz innerhalb eines Polymers kontrolliert werden kann.
Gerade bei den großtechnisch bedeutsamen radikalischen Polymerisationen ist die Sequenzkontrolle schwierig, weil die chemischen Bausteine (Monomere) sehr reaktiv sind. Im ersten Teil dieser Arbeit werden die Eigenschaften zweier Monomere (Styrol und N-substituiertes Maleinimid) geschickt ausgenutzt, um in eine Styrolkette definierte und lokal scharf abgegrenzte Funktionssequenzen einzubauen. Uber eine kontrollierte radikalische Polymerisationsmethode (ATRP) wurden in einer Ein-Topf-Synthese über das N-substituierte Maleinimid chemische Funktionen an einer beliebigen Stelle der Polystyrolkette eingebaut. Es gelang ebenfalls, vier unterschiedliche Funktionen in einer vorgegebenen Sequenz in die Polymerkette einzubauen. Diese Technik wurde an zwanzig verschiedenen N-substituierten Maleinimiden getestet, die meisten konnten erfolgreich in die Polymerkette integriert werden.
In dem zweiten in dieser Arbeit vorgestellten Ansatz zur Sequenzkontrolle, wurde der schrittweise Aufbau eines Oligomers aus hydrophoben und hydrophilen Segmenten (ω-Alkin-Carbonsäure bzw. α-Amin-ω-Azid-Oligoethylenglycol) an einem löslichen Polymerträger durchgeführt. Das Oligomer konnte durch die geschickte Auswahl der Verknüpfungsreaktionen ohne Schutzgruppenstrategie synthetisiert werden. Der lösliche Polymerträger aus Polystyrol wurde mittels ATRP selbst synthetisiert. Dazu wurde ein Startreagenz (Initiator) entwickelt, das in der Mitte einen säurelabilen Linker, auf der einen Seite die initiierende Einheit und auf der anderen die Ankergruppe für die Anbindung des ersten Segments trägt. Der lösliche Polymerträger ermöglichte einerseits die schrittweise Synthese in Lösung. Andererseits konnten überschüssige Reagenzien und Nebenprodukte zwischen den Reaktionsschritten durch Fällung in einem Nicht-Lösungsmittel einfach abgetrennt werden. Der Linker ermöglichte die Abtrennung des Oligomers aus jeweils drei hydrophoben und hydrophilen Einheiten nach der Synthese. / Polymer scientists are impressed by polymers created by nature. This is caused by their structure which is aimed to fulfill very special functions. The structure is primary built by sequential covalent linking of building units. Secondly, supramolecular aggregation leads to three-dimensional alignment. The sequence of the building blocks has a high influence on the higher molecular arrangement. Proteins are only one example for supramolecular structures which have special functions because of their supramolecular arrangement. This structure-property relationship is also possible for synthetic polymers. For this reason the control of monomer sequences in synthtic polymers is just as important for the resulting structure of a synthetic polymer molecule.
Even though the synthesis of polymers with complex strucures and sizes as in nature is impossible in near future. But the development of new and better techniques for sequence control in synthetic polymers is of high importance to create well defined macromolecular structures which are tailor-made for their function.
In contrast to a lot of advanced synthethis strategies for the design of complex polymer architechtures (e.g. brushes, stars, or dendrimers) their are less approaches for a monomer sequence control in synthetic polymers. This work presents two different techniques for controlling the monomer sequence inside a polymer.
Especially in technologically significant radical polymerization it is difficult to control the monomer sequence because radical species are very reactive and the addition of a monomer to the radical function is not selective. The first approach makes use of the properties of two monomers (styrene and N-substituted maleimides) to add chemical funtions locally inside a polystyrene chain. By addition of N-functionalized maleimides during the polymerization of styrene chemical functions could be added at any desired position inside the polystyrene chain. This technique was tested on 20 different N-substituted maleimides. Most of them were incorporated successfully into the polymer chain.
The second monomer sequence control approach is a stepwise synthesis of an oligomer made of short alternating hydrophobic and hydrophilic segments on a soluble polymer support. Two building blocks were used: ω-alkyne carboxylic acid (A-B) and α-amine-ω-azide oligoethylene glycol (C-D). The linking of the segments was done by applying two very efficient chemical reactions, namely 1,3-dipolar cycloaddition of terminal alkynes (A) and azides (D) and amidification of carboxylic acids (B) with primary amines (C). These two reactions proceed chemoselectively in an ABCD multifunctional mixture without a protection chemistry strategy.
The polystyrene support was synthesized by atom transfer radical polymerization (ATRP) in the presence of an azido-functionalized ATRP initiator containing a labile p-alkoxybenzyl ester linker. Depending on the choise of solvent, the soluble polymer support was used in solution during the coupling reactions or was precipitated for an easy removal of excessive reagents and by-products. The acid-labile linker could be cleaved by trifluoroacetic acid treatment to obtain a hydrophilic/hydrophobic block copolymer.
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Electrochemical Polymerization of Thiophene Derivatives and its Applicability as the Cathode Material of Li-Ion BatteryHer, Li-jane 07 February 2006 (has links)
Electrochemical copolymerizations of thiophene (Th) and 3,4-ethylenedioxythiophene (EDOT) was performed in this study. Incorporation of Th with EDOT units have accelerated deposition rate in relative to the simple polymerization behavior of EDOT. The electrochemical properties of poly(thiophene-co-3,4-ethylenedioxythiophene) (PTh-EDOT) are different from the homopolymers of polythiophene (PTh) and poly(3,4-ethylenedioxythiophene) (PEDOT). PTh-EDOT were then served as cathode materials of lithium-ion (Li-ion) batteries to test their capability to transfer lithium ion in 1.0 M LiPF6/ethylene carbonate/dimethyl carbonate solution. PTh-EDOT copolymer prepared from the monomer ratio of 1/1 (Th/EDOT) shows better stability than PEDOT and PTh homopolymers, polymer property enhancement by copolymerization is thus demonstrated.
A composite electrode material PEDOT/LiCoO2 was prepared from the electrochemical polymerization of EDOT on LiCoO2 electrode was primarily prepared to inspect the influence of PEDOT on the electrochemical features of LiCoO2. Scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) show the successful deposition of PEDOT over LiCoO2 particles. Compared to the simple LiCoO2 electrode, PEDOT/LiCoO2 composite cathode shows enhanced properties including rate capability and cycle stability for potential Li-ion battery application. Nevertheless, differential scanning calorimetry (DSC) scans on the fully charged cathodes imply that PEDOT may reduce the thermal stability of LiCoO2.
Two carbon materials, vapor grown carbon fibers (VGCF) and nano-scaled Ketjen black EC (KB), were implemented into LiCoO2 electrode. The influence of different carbon additive and their content on the performance of LiCoO2 such as rate capability and cycle ability has been evaluated. KB shows more positive effects than VGCF even in the case of a low 1 wt% content. Furthermore, incorporation of PEDOT was made by electrochemical deposition of EDOT on the preformed LiCoO2-VGCF and LiCoO2-KB composite electrodes. The influence of the carbon additives and the conductive PEDOT polymer on LiCoO2 was then investigated. Compared to the electrodes without PEDOT coating, PEDOT-incorporated composite electrodes show larger capacity, better transfer rate of lithium ions in electrolytes, and enhanced cycle ability. The electrochemical deposition of PEDOT on the LiCoO2/nano-carbon cathodes provides a new approach to implement the conducting polymers in Li-ion batteries.
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Syntheses Of Conducting Polymers Of 3-ester Substituted Thiophenes And Characterization Of Their Electrochromic PropertiesCamurlu, Pinar 01 September 2003 (has links) (PDF)
In this study three different 3-ester substituted thiophene monomers were synthesized via esterification reaction of 3-thiophene ethanol with adipoyl chloride or sebacoyl chloride or octanoyl chloride in the presence of triethylamine at 00C. Characterizations of the monomers were performed by 1H-NMR, 13C-NMR, FTIR, DSC, TGA techniques. Electrochemical behavior of the monomers both in presence or absence of BFEE were studied by cyclic voltammetry. Results showed the astonishing effect of BFEE on the polymerization, where free standing films of the homopolymers could be synthesized. Copolymers of the monomers with thiophene or 3-methyl thiophene were synthesized at constant potential electrolysis and the resultant polymers were characterized by FTIR, DSC, TGA, SEM and conductivity measurements. Second part of the study was devoted to investigate the one of most interesting property of conducting polymers, the ability to switch reversibly between the two states of different optical properties, &lsquo / electrochromism&rsquo / . In recent years there has been a growing interest in application of conducting polymers in electrochromic devices. Thus, electrochromic properties of the synthesized conducting polymers were investigated by several methods like spectroelectrochemistry, kinetic and colorimetry studies. Spectroelectrochemistry experiments were performed in order to investigate key properties of conjugated polymers such as band gap, maximum absorption wavelength, the intergap states that appear upon doping and evolution of polaron and bipolaron bands. Switching time and optical contrast of the homopolymers and copolymers were evaluated via kinetic studies. Results implied the possible use of these materials in electrochromic devices due to their satisfactory electrochromic properties like short switching time and stability. Generally the homopolymers displayed color changes between yellow, green and blue colors upon variation of applied potentials. Fine tuning of the colors of the polymers were accomplished by techniques like copolymerization and lamination. These studies were supported with experiments like spectroelectrochemistry and FTIR. Results showed the possible control of the color of the electrochromic material in a predictable, controlled and reproducible manner. Yet, it was possible to achieve different tones of yellow, green, orange color in neutral state of these materials. As the last part of the study, dual type electrochromic devices based on polymers of 3-ester substituted thiophenes with poly(3,4-ethylenedioxythiophene) were constructed, where the former and the later functioned as anodically and cathodically coloring layers respectively. Spectroelectrochemistry, switching ability, stability, open circuit memory and color of the devices were investigated and the results revealed that these devices have satisfactory electrochromic parameters.
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Graft Copolymerization Of P-acryloyloxybenzoic Acid Onto High Density PolyethyleneCagirici, Seda 01 December 2003 (has links) (PDF)
The monomer, p-acryloyloxybenzoic acid (ABA) was synthesized by condensation reaction of acryloyl chloride and p-hydroxybenzoic acid in alkaline medium. Polymerization of the monomer and grafting of the produced
polymer (PABA) onto high density polyethylene (HDPE) were expected to be carried simultaneously in melt mixing at high temperature. The graft copolymerization was studied at varying concentrations of the monomer in the reaction mixture at constant temperature (200 0C).
Grafted HDPE samples were investigated by several techniques such as DSC, FTIR, MFI and mechanical testing.
The tensile tests of PABA-g-HDPE showed an improvement particularly in stress at yield and Young&rsquo / s modulus whereas the strain at break values showed a decrease for all compositions compared to neat HDPE.
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Novel Donor-acceptor Type Green Polymer Bearing Pyrrole As The Donor Unit With Excellent Switching Times And Very Low Band Gap And Its Multichromic CopolymersCelebi, Selin 01 September 2009 (has links) (PDF)
A new neutral state green polymer, poly (2,3-bis(4-tert-butylphenyl)-5,8-di(1H-pyrrol-2-yl) quinoxaline) (PTBPPQ) was synthesized and its copolymer with bis(3,4-ethylenedioxythiophene) (BiEDOT) and 4,7-bis(2,3-dihydrothieno[3,4-b][1,4]dioxin-5-yl)-2-dodecyl-2H-benzo [1,2,3] triazole (BEBT) were produced. Finally polymers&rsquo / potential use as an electrochromic material was investigated. Electrochromic properties of the polymers were investigated by several methods including spectroelectrochemistry, kinetic and colorimetry studies. Key properties of conjugated polymers such as band gap, maximum absorption wavelength, the intergap states that appear upon doping and evolution of polaron and bipolaron bands were investigated via spectroelectrochemistry experiments. Switching times and optical contrasts of the homopolymer and the copolymer were evaluated via kinetic studies. Copolymer of TBPPQ with BiEDOT and BEBT were electrochemically synthesized and characterized. Resulting copolymer films have distinct electrochromic properties and revealed multichromism through the entire visible region. Although BiEDOT and BEBT have different oxidation potentials, the resulting copolymers have very similar redox behaviors. In a monomer free solution, both copolymers show four colors from purple, gray, light green to transmissive blue with the variation of the applied potential. Copolymerization with BiEDOT and BEBT not only decreases the band gap, Eg, but also enhances the electrochromic and optical properties. Hence, electrochemical copolymerization is considered to be a powerful tool to improve the electrochromic properties of quinoxaline derivatives. It should be noted that PTBPPQ is one of the few examples of neutral state green polymeric materials with superior switching properties. Hence, PTBPPQ can be used as a green polymeric material for display technologies.
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Mikro- und makroskopische Eigenschaften von statistisch und nicht-statistisch aufgebauten Copolymeren / Radikalische Polymerisationen in einem weiten Zustandsbereich bis hin zu hohen Drücken und Temperaturen / Properties of random and non-random copolymers / poly(ethylene-co-methacrylic acid): synthesis and characterizationSteisel, Björn 01 November 2007 (has links)
No description available.
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Synthesis And Electrochromic Properties Of Conducting Copolymers Of Dioxocino- And Dithiocino- Quinoxalines With BithiopheneBeyazyildirim, Seniz 01 June 2005 (has links) (PDF)
Two new monomers / 2-benzyl-5,12-dihydro-2Hpyrrolo[
3&rsquo / ,4&rsquo / :2,3][1,4]dioxocino[6,7-b]quinoxaline (DPOQ) and 5,12-
dihydrothieno[3&rsquo / ,4&rsquo / :2,3][1,4]dithiocino[6,7-b]quinoxaline (DTTQ), were synthesized.
The chemical structures of the monomers were characterized by Nuclear Magnetic
Resonance (1H-NMR), Fourier Transform Infrared (FTIR) and Mass Spectrometry
(MS). Copolymer of DPOQ with bithiophene (BT) was synthesized via potentiostatic
electrochemical polymerization in acetonitrile (ACN)-tetrabutylammonium
tetrafluoroborate (TBAFB) solvent-electrolyte couple. For DTTQ, copolymerization
with bithiophene was achieved via potentiodynamic method in dichloromethane
(DCM)-tetrabutylammonium hexafluorophosphate (TBAFP) solvent-electrolyte
couple. Characterizations of the resulting copolymers were performed by cyclic
voltammetry (CV), FTIR, Scanning Electron Microscopy (SEM) and UV-Vis
Spectroscopy. Four-probe technique was used to measure the conductivities of the
samples. Moreover, the spectroelectrochemical and electrochromic properties of the
copolymer films were investigated. In addition, dual type polymer electrochromic
devices (ECDs) based on P(DPOQ-co-BT) and P(DTTQ-co-BT) with poly(3,4-
ethylenedioxythiophene) (PEDOT) were constructed. Spectroelectrochemistry,
electrochromic switching and open circuit stability of the devices were studied. They
were found to have good switching times, reasonable contrasts and optical memories.
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Copolymerisation Of Carbon Disulfide, Carbon Dioxide And Other Carbonic Acid Derivatives With Cyclic Ethers By Using Metal Xanthate CatalystsOzturk, Elif 01 May 2006 (has links) (PDF)
The synthesis of high molecular weight copolymer of carbon disulphide (CS2) and propylene oxide (PO) has not reported in literature. In the present work, zinc isopropyl xanthate (Zn(Xt)2) was used as catalyst for the copolymerisation of PO and CS2 into high copolymer. However, the product can be fractionated into high and low molecular weight components. High molecular weight copolymer was rubbery products, but low molecular weight copolymers were oily products containing cyclic dithiocarbonates. Copolymers were characterized by elemental, end group analysis, DSC, TGA, GPC, Light Scattering, UV, IR, NMR spectroscopy, polarized microscopy and refractometry.
Copolymerization process was zeroth order with respect to monomers, and its non-terminated but suffered from several types of transfer reactions. As a result of transfer reactions S-(C=S)-S, O-(C=S)-O, O-(C=O)-O groups in the backbone of copolymer and SH groups at the chain terminals and cyclic dithiocarbonates are formed. Apart from SH groups, OH and double bonds were found and their amounts were
determined at the chain terminals. Copolymers with high mole fractions of PO units (F1) in the copolymer are crystallized in the shape of Malta& / #8217 / s Cross. Melting points of products were obtained from DSC. The F1 values are calculated from elemental analysis as well as zeroth order rate constants and from melting point of the crystals. All three results were in close agreement and changed between 0.9 & / #8211 / 0.7. However, these ratios depend on reaction conditions (temperature, catalyst and monomer concentrations, time and dielectric constant of reaction medium).
A mechanism for coordination-copolymerization on the basis of above observation was proposed.
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