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Molecular chains compounds

Most properties of linear polymers are controlled by two different factors. The chemical constitution of tire monomers detennines tire interaction strengtli between tire chains, tire interactions of tire polymer witli host molecules or witli interfaces. The monomer stmcture also detennines tire possible local confonnations of tire polymer chain. This relationship between the molecular stmcture and any interaction witli surrounding molecules is similar to tliat found for low-molecular-weight compounds. The second important parameter tliat controls polymer properties is tire molecular weight. Contrary to tire situation for low-molecular-weight compounds, it plays a fimdamental role in polymer behaviour. It detennines tire slow-mode dynamics and tire viscosity of polymers in solutions and in tire melt. These properties are of utmost importance in polymer rheology and condition tlieir processability. The mechanical properties, solubility and miscibility of different polymers also depend on tlieir molecular weights. [Pg.2514]

The terminal groups of a polymer chain are different in some way from the repeat units that characterize the rest of the molecule. If some technique of analytical chemistry can be applied to determine the number of these end groups in a polymer sample, then the average molecular weight of the polymer is readily evaluated. In essence, the concept is no different than the equivalent procedure applied to low molecular weight compounds. The latter is often included as an experiment in general chemistry laboratory classes. The following steps outline the experimental and computational essence of this procedure ... [Pg.30]

Before concluding this section, there is one additional thermodynamic factor to be mentioned which also has the effect of lowering. Since we shall not describe the thermodynamics of polymer solutions until Chap. 8, a quantitative treatment is inappropriate at this point. However, some relationships familiar from the behavior of low molecular weight compounds may be borrowed for qualitative discussion. The specific effect we consider is that of chain ends. The position we take is that they are foreign species from the viewpoint of crystallization. [Pg.217]

Viscosities of the siloxanes were predicted over a temperature range of 298-348 K. The semi-log plot of viscosity as a function of temperature was linear for the ring compounds. However, for the chain compounds, the viscosity increased rapidly with an increase in the chain length of the molecule. A simple 2-4-1 neural network architecture was used for the viscosity predictions. The molecular configuration was not considered here because of the direct positive effect of addition of both M and D groups on viscosity. The two input variables, therefore, were the siloxane type and the temperature level. Only one hidden layer with four nodes was used. The predicted variable was the viscosity of the siloxane. [Pg.12]

Like PEO-LiCl04, a 6 1 crystalline compound is formed but, in this instance, the weakened interactions between polymer chains [18] contributes to the lowest melting point for any PEO-salt crystalline complex. A eutectic with composition 0 Li = 11 1 forms, provided the PEO molecular chain length is beyond the entanglement threshold [31]. For lower molecular weights, the 6 1 compound dose not crystallize in the presence of excess PEO and a crystallinity gap exists over the range 6 l < 0 Li < 12 1 [26]. [Pg.504]

Lower the viscosity of natural rubber as a result of breaking of the molecular chains to enable problem-free compounding with saving of cost and time. Without the presence of oxygen, mastication would not be possible. The consequence of mastication is a reduction of average molecular weight. [Pg.781]

On the contrary, for oil E the quantity of asphaltenes decreases from 8.1 for the initial crude oil to 4-1 for the sample produced at the end of the test (Fig. 12). Moreover, the amounts of resins + asphaltenes decreases whereas the amounts of saturates and aromatics increase (51 4 in the initial oil, 72.4 for a sample recovered at t = 24 h). The analysis by GC shows that each oil fraction is enriched in components with molecular chains ranging from 15 to 30 carbons which don t exist in the initial oil (n-alkanes, aromatics O q-CLq which are less complex than the initial ones, thiophenic compounds C -C ). The elemental... [Pg.422]

Arts. These compounds can each form isomers (having the same molecular formulas). C4H,0 can occur as a straight-chain compound and a branched-chain compound. C3H6 can occur with a double bond or in a ring. [Pg.330]

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Chain compounds

Molecular chains

Molecular compounds

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