Poly chain structure

Chain Structure. The chemical composition of poly (vinyhdene chloride) has been confirmed by various techniques, including elemental analysis, x-ray diffraction analysis, degradation studies, and in, Raman, and nmr spectroscopy. The polymer chain is made up of vinyhdene chloride units added head-to-tail ... 

The cohesive energy per carbon atom in a poly-yne ring is only 99.1 kcal/mol, clearly lower than the value in Cc. Anticipating a long and complicated route of formation when starting from graphite, in does not seem likely that any of the larger clusters observed experimentally would have a linear or cyclic chain structure. 

Analogous principles should apply to ionically propagated polymerizations. The terminus of the growing chain, whether cation or anion, can be expected to exhibit preferential addition to one or the other carbon of the vinyl group. Poly isobutylene, normally prepared by cationic polymerization, possesses the head-to-tail structure, as already mentioned. Polystyrenes prepared by cationic or anionic polymerization are not noticeably different from free-radical-poly-merized products of the same molecular weights, which fact indicates a similar chain structure irrespective of the method of synthesis. In the polymerization of 1,3-dienes, however, the structure and arrangement of the units depends markedly on the chain-propagating mechanism (see Sec. 2b). 

Upon applying the calibration constants obtained from the data of one sample to evaluate the SEC data of the other samples, the calculated Mn and values correspond fairly well (within 10-20%) with the absolute MW parameters of the samples. This agreement also suggests that the samples probably have similar chain structures. The distribution functions for samples PN-1 and IL-22 are plotted in Figures 4 and 5. The molecular weight distributions of both polymers are similar to distribution curves reported for derivatized poly(organo)phosphazenes (4-10). 

An overview of the synthesis and characterization of a unique class of polymers with a phosphorus-nitrogen backbone Is presented, with a focus on poly(dichloro-phosphazene) as a common Intermediate for a wide variety of poly(organophosphazenes). Melt and solution polymerization techniques are Illustrated, Including the role of catalysts. The elucidation of chain structure and molecular weight by various dilute solution techniques Is considered. Factors which determine the properties of polymers derived from poly(dichlorophos-phazene) are discussed, with an emphasis on the role that the organic substituent can play In determining the final properties. 

Coordination studies of acyclic thioether ligands to silver(I) centers has also been studied. Poly(alkylthio)aromatic systems have been used to form supramolecular silver(I) compounds. With the ligand 2,3,5,6-tetrakis(isopropylthio)benzoquinone the compound has a linear chain structure in which silver(I) has a tetrahedral coordination.1156 A similar structure has the compound with the hexakis(methylthio)benzene,1157 but with the hexakis(tolylthio)benzene the silver... 

Figure 16 Chain structure of poly(p-phenylene terephthalamide) (Kevlar ).

MHz, which determine the Tics, are the same for the non-crystalline region of isotactic poly(propylene) and for atactic poly(propylene). This in turn indicates that the disordered chain structure is the same for the two cases. 

A similar comparison can be made with cis-poly(isoprene), natural rubber, by taking advantage of the fact that the polymer is very slow to crystallize [164], Consequently, the comparison can be made between the supercooled, noncrystalline polymers at 0°C and the semi-crystalline polymer (31% crystalline) at the same temperature. The Tlc values for each of the five carbons involved were again found to be the same for the completely disordered polymer and the semicrystalline one, so that a similar conclusion can be made with regard to their chain structure. 

It is considered that, if ideal, optically active poly(alkyl(aryl)silane) homopolymer and copolymer systems could be obtained which had stiffer main-chain structures with longer persistence lengths, it should be possible to clarify the relationship between the gabs value and the chiral molar composition. The magnitude of the chirality of the polyisocyanates allowed precise correlations with the cooperativity models.18q In the theory of the cooperative helical order in polyisocyanates, the polymers are characterized by the chiral order parameter M, which is the fraction of the main chain twisting in one helical sense minus the fraction of the main chain twisting in the opposing sense. This order parameter is equal to the optical activity normalized by the value for an entirely one-handed helical polymer. The theory predicts... 

Other efforts based on the macromonomer approach to homopolymers having dendritic side chains, include the work of Draheim and Ritter on acrylate and methacrylate derived structures having dendritic chiral side chains based on L-aspartic esters [17a], and of Xi and coworkers with poly(methacrylate) structures containing very small benzyl ether dendritic side-chains [17b]. Unfortunately, both of these approaches met with limited success due to a significant drop in degree of polymerization (DP) when the size of the dendron used as pendant group in the macromonomers increased from G-l to G-2. 

Poly(n-alkyl isocyanate) compounds have a rigid helical structure in solution (174). As shown in Scheme 74, a chirally deuterium-labeled isocyanate is polymerized by sodium cyanide to form a product with a very high rotation value (175). The rotation is highly temperature dependent because of the unique chain structure of the product. Interestingly, the reaction of hexyl isocyanate in the presence of 1 mol % of a related chiral analogue leads to a polymer with a high rotation value. The bias of the chain helicity could be induced by living achiral-chiral copolymers. 

Reaction LXVIH. Simultaneous Reduction and Halogenation of Poly-hydric Alcohols. (A., 138, 364.)—When polyhydric alcohols are heated with hydriodic acid, reduction of all the hydroxyl groups save one occurs this latter is replaced by iodine to form a secondary iodide. In this way, e.g., dulcitol, or any of the hexose alcohols, yields normal secondary hexyl iodide this is of importance in determining the chain structure of the sugars. This reaction probably occurs—... 

The effect of the side chain structure on the solution behavior as well as in the solid state of vinyl polymers has been studied in the past for a number of poly(methacrylate)s [72,73,76], The conformational study of polymers containing... 

According to the results shown for these polymers, the effect of the side chain structure on the viscoelastic and thermal behavior, play an important role. The effect of the carboxylic group by one hand and the length of the hydrophobic side chain on the other, are the driving forces responsible of the relaxational behavior in this family of poly(itaconate)s. 

The effect of the side chain structure on the relaxational behavior of poly (itaconate)s was studied by Diaz Calleja and coworkers [238] in a family of poly(di-n-alkyl and diisoalkylitaconate)s. Specifically in poly(dimethyl itaconate) (PDMI), poly(diethylitaconate) (PDEI), poly(di-n-propyl itaconate) (PDPI), poly (di-n-butylitaconate) (PDIBI), poly(diisopropylitaconate) (PDIPI) and poly (diisobutylitaconate) (PDIBI). These systems show three dielectric relaxation processes, labelled as a, /3 and y. Nevertheless, in some polymers a poor resolution of... 

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