posted on 2021-02-10, 12:12authored byMilad Asgarpour Khansary, Peyman Pouresmaeel-Selakjani, Mohammad Ali Aroon, Ahmad Hallajisani, Jennifer Cookman, Saeed Shirazian
The native cellulose, through TEMPO (2,2,6,6-tetramethylpiperidine-1-oxyl radical)-mediated oxidation, can be
converted into individual fibers. It has been observed that oxidized fibers disperse completely and individually in
water. It is believed that electrostatic repulsive forces might be responsible for such observations. In order to study
the TEMPO-oxidation of cellulose molecules, we used Density Functional Theory (DFT) calculations and FloryHuggins theory combined with molecular dynamics (MD). The surface electrostatic potential in native cellulose
and TEMPO-oxidized cellulose were calculated using DFT calculations. We found that TEMPO-oxidized cellulose
accommodates a threefold screw conformation where the negatively charged (–COO–) functional groups are
pointed away from the surface in all spatial directions. This spatial orientation causes that TEMPO-oxidized
cellulose molecules repulse each other due to strong negatively charged surface. At the same time, the spatial
orientation increases the hydrophilicity in TEMPO-oxidized cellulose molecules. These observations explain the
improved dispersion in water and separability of TEMPO-oxidized cellulose molecules. We obtained large and
positive Flory–Huggins interaction parameters for TEMPO-oxidized cellulose molecules indicating their higher
dispersion once in water.