Moderate strains, statistical

Comparison with Statistical Theory at Moderate Strains. So far we have shown, that a transition between the two limiting classical theories, i.e. affine theory and phantom theory, is possible by a suitable choice of the network microstructure. This argument goes beyond the revised theory by Ronca and Allegra and by Flory, which predicts such a transition as a result of increasing strain, thus explaining the experimentally observed strain dependence of the reduced stress. 

The presence of filler in the rubber as well as the increase of the surface ability of the Aerosil surface causes an increase in the modulus. The temperature dependence of the modulus is often used to analyze the network density in cured elastomers. According to the simple statistical theory of rubber elasticity, the modulus should increase twice for the double increase of the absolute temperature [35]. This behavior is observed for a cured xmfilled sample as shown in Fig. 15. However, for rubber filled with hydrophilic and hydrophobic Aerosil, the modulus increases by a factor of 1.3 and 1.6, respectively, as a function of temperature in the range of 225-450 K. It appears that less mobile chain units in the adsorption layer do not contribute directly to the rubber modulus, since the fraction of this layer is only a few percent [7, 8, 12, 21]. Since the influence of the secondary structure of fillers and filler-filler interaction is of importance only at moderate strain [43, 47], it is assumed that the change of the modulus with temperature is mainly caused by the properties of the elastomer matrix and the adsorption layer which cause the filler particles to share deformation. Therefore, the moderate decrease of the rubber modulus with increasing temperature, as compared to the value expected from the statistical theory, can be explained by the following reasons a decrease of the density of adsorption junctions as well as their strength, and a decrease of the ability of filler particles to share deformation due to a decrease of elastomer-filler interactions. 

ECB deacylase is an 81-83-kDa heterodimer consisting of 63- and 18-20-kDa subunits. Penicillin G acylase from Escherichia coli is an 87-kDa heterodimer with 65- and 22-kDa subunits [32], For comparison, cephalosporin acylase from a Pseudomonas strain is an 83-kDa heterodimer consisting of 57- and 26-kDa subunits [33], The essential absence of any external catalytic requirement, cofactor stimulation, or product inhibition of ECB deacylase is also an intrinsic property of penicillin acylase [34], Based on the amino-terminal sequences of the two subunits of ECB deacylase, a 48% sequence similarity has been observed between the small subunit of ECB deacylase and a penicillin acylase [25]. This statistically significant albeit moderate sequence similarity from two short segments of the enzymes suggests an evolutionary relationship between ECB deacylase and peni-... 

Stress-strain properties for unfilled and filled silicon rubbers are studied in the temperature range 150-473 K. In this range, the increase of the modulus with temperature is significantly lower than predicted by the simple statistical theory of rubber elasticity. A moderate increase of the modulus with increasing temperature can be explained by the decrease of the number of adsorption junctions in the elastomer matrix as well as by the decrease of the ability of filler particles to share deformation caused by a weakening of PDMS-Aerosil interactions at higher temperatures. 

The statistical approach, using a Gaussian distribution, thus appears to predict the stress-strain response except at moderately high elongations. 

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