Химико биологическая серия 1 2014
ISSN 1811-184X. Вестник ПГУ
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| ISSN 1811-184X. Вестник ПГУ
серия ХИМИКО - БИОЛОГИЧЕСКАЯ. 2014. № 1 12 13 They showed that it is based on the elastic instability of the external layer of the swollen gel that during swelling becomes strongly compressed in the tangential directions due to connection with unswollen core of gel. A similar explanation was given by other authors [3-4], which suggested a more rigorous theoretical description of the phenomenon, including nonlinear effects. Characteristic swelling kinetics of weakly crosslinked polymer hydrogels is certain present scientific interest and has great practical significance. Scientific interest related in particular to the fact that research of the kinetics of swelling gives an indication of the dynamics of the thermal fluctuations of the polymer concentration in the gel. The practical importance caused, for example, that the swelling kinetics can determine the performance of the gel as a moisture absorbent. Influence of mesh density and size of the sample gel was studied on the example of hydrogels with strongly dissociating ionic groups, prepared by radiation crosslinking aqueous solution (c = 4.1 wt.%) аnd vinyl sulfonic acid copolymer isopropylacrylamide (30 mol.%) аt different doses of γ-radiation (Figure 1). As can be seen, the degree of swelling (Q) increases rapidly in the initial stage of swelling and is slowly coming to its equilibrium value at large times. The characteristic time of swelling increases with decreasing mesh density (radiation dose) and the increase of sample size. Figure 1 - Kinetics of swelling of charged gels in water: influence of mesh density and sample size The kinetics of swelling of the polyelectrolyte gel depends on the ionic composition of the solution in which the swelling. This process is shown in the study of the swelling caused by a stepwise decrease in salt concentration (NaCl) in the aqueous solution surrounding the gel. The results of this experiment are presented in Figure 2. Quantitative analysis of the experimental data was carried out in the framework of the model proposed by Tanaka [2]. To do this, the degree of swelling and the initial size of the gel found its current size r (for example, the radius of the cylinder), assuming that all sample sizes increase with swelling in proportion to each other, and the difference between the final (equilibrium) and the current size of the gel r r r − = ∆ ∞ was plotted on a logarithmic depending on the scale of time. Figure 2 - The polyelectrolyte hydrogel swelling kinetics in an aqueous solution of NaCl with stepwise decreasing salt concentration from 3.0 to 0.90 (1) 0.90 to 0.27 (2) 0.27 to 0.08 (3) 0.08 to 0.034 (4) 0.034 to 0.015 and mol / l (5). In these experiments the characteristic swelling time τ1 is almost independent of the size of the equilibrium gel r. Found parameter B 1 was used to assess for the modules G/M. The value of G/M was determined by theoretical dependences B 1
of G/M derived for gels in the form of a sphere [3]. |