Abstract
Trehalose is chosen as a model molecule to investigate the dissolution mechanism of cellulose in NaOH/urea aqueous solution. The combination of neutron total scattering and empirical potential structure refinement yields the most probable all-atom positions in the complex fluid and reveals the cooperative dynamic effects of NaOH, urea, and water molecules in the dissolution process. NaOH directly interacts with glucose rings by breaking the inter- and intra-molecular hydrogen bonding. Na+, thus, accumulates around electronegative oxygen atoms in the hydration shell of trehalose. Its local concentration is thereby 2–9 times higher than that in the bulk fluid. Urea molecules are too large to interpenetrate into trehalose and too complex to form hydrogen bonds with trehalose. They can only participate in the formation of the hydration shell around trehalose via Na+ bridging. As the main component in the complex fluid, water molecules have a disturbed tetrahedral structure in the presence of NaOH and urea. The structure of the mixed solvent does not change when it is cooled to −12 °C. This indicates that the dissolution may be a dynamic process, i.e., a competition between hydration shell formation and inter-molecule hydrogen bonding determines its dissolution. We, therefore, predict that alkali with smaller ions, such as LiOH, has better solubility for cellulose.
Highlights
Cellulose is one of the most abundant natural polymers in the world
O1 links the two glucopyranose rings, and O2 forms part of the glucose rings, so they are located inside the trehalose molecule, while O3 and O4 belong to hydroxyl groups that are located on the periphery
Trehalose has been used as a model molecule to investigate the mechanism of rapid dissolution of cellulose in an NaOH/urea aqueous solution at two different temperatures
Summary
Cellulose is one of the most abundant natural polymers in the world. For example, its content in wood is 33%–51%, its content in flax reaches 63%–71%, and its content in cotton is an amazing 83%–95%. NMR observations in energy space, the current explanation is that NaOH directly interacts with cellulose, and urea forms a hydration shell around this “NaOH hydrogen bonded cellulose,” forming an inclusion complex (IC).. We used trehalose as a model solute for cellulose, and neutron total scattering as the main tool to study the dissolution mechanism. Neutron total scattering, combined with empirical potential structure refinement (EPSR), is a nondestructive method to determine the most-probable all-atom positions in the complex fluid (we call the four-component system, i.e., trehalose in urea/NaOH aqueous solution, complex fluid thereafter). It is found that NaOH, urea, and water work cooperatively to dissolve trehalose. The fact that the molecular structure of the mixed solvent does not change significantly when it is cooled to À12 C, indicating a dynamic dissolution mechanism
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