Analysis of the sulfuric acid hydrolysis of wood pulp for cellulose nanocrystal production: A central composite design study

Abstract

Cellulose nanocrystals (CNCs) are most commonly prepared by sulfuric acid hydrolysis of a purified cellulose starting material but the effects of hydrolysis conditions on CNC yield and properties are incompletely understood. In this study, we use a rotatable central composite experimental design to elucidate parameter interactions between three design factors, acid concentration (x1), hydrolysis temperature (x2), and hydrolysis time (x3), over a broad range of process conditions and determine their effect on yield and sulfate group density. Parameter ranges are 55–65wt.% for x1, 45–65°C for x2, and 30–180min for x3. Regression models of the experimental yield data reveal significant two-factor interactions of x1 with each x2 and x3, whereas x2 has no significant two-factor interaction with x3. The models predict maximum yields of 66–69% at optimum process conditions of 57–58wt.% (x1), 64–67°C (x2), and 134–156min (x3). At these conditions, the sulfate group density is predicted to be between 241 and 265mmol/kg. The sulfate group density is linearly dependent on acid concentration and hydrolysis temperature and not dependent on hydrolysis time. Maximum sulfate group density can only be achieved at the expense of yield. The results presented here provide a foundation for subsequent, sequential optimization using narrower parameter ranges, allowing further optimization of the hydrolysis conditions and potentially enabling higher yield.