Journal
MATERIALS
Volume 16, Issue 7, Pages -Publisher
MDPI
DOI: 10.3390/ma16072565
Keywords
artificial neural networks; chemical modification; rheological behavior; xanthan gum
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The main objective of this study was to create a mathematical tool that could predict the rheological flow behavior of functionalized xanthan gum based on the types of chemical groups grafted onto its backbone. Different analyses were done to evaluate six derivatives synthesized via etherification, and it was found that the derivatives had lower molecular weights and exhibited shear-thinning behavior. An ANN model was also created to predict one of the rheological properties, and the results showed that the model was efficient in predicting flow behavior.
The main objective of this study was to create a mathematical tool that could be used with experimental data to predict the rheological flow behavior of functionalized xanthan gum according to the types of chemical groups grafted onto its backbone. Different rheological and physicochemical analyses were applied to assess six derivatives synthesized via the etherification of xanthan gum by hydrophobic benzylation with benzyl chloride and carboxymethylation with monochloroacetic acid at three (regent/polymer) ratios R equal to 2.4 and 6. Results from the FTIR study verified that xanthan gum had been modified. The degree of substitution (DS) values varying between 0.2 and 2.9 for carboxymethylxanthan gum derivatives were found to be higher than that of hydrophobically modified benzyl xanthan gum for which the DS ranged from 0.5 to 1. The molecular weights of all the derivatives were found to be less than that of xanthan gum for the two types of derivatives, decreasing further as the degree of substitution (DS) increased. However, the benzyl xanthan gum derivatives presented higher molecular weights varying between 1,373,146 (g/mol) and 1,262,227 (g/mol) than carboxymethylxanthan gum derivatives (1,326,722-1,015,544) (g/mol). A shear-thinning behavior was observed in the derivatives, and the derivatives' viscosity was found to decrease with increasing DS. The second objective of this research was to create an ANN model to predict one of the rheological properties (the apparent viscosity). The significance of the ANN model (R-2 = 0.99998 and MSE = 5.95 x 10(-3)) was validated by comparing experimental results with the predicted ones. The results showed that the model was an efficient tool for predicting rheological flow behavior.
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