Controlling the nanocellulose morphology by preparation conditions

Nanocellulose (NC) is the desired building block for novel biomaterials. The morphology of NC is one of the core parameters impacting the functionality and property of engineered functional materials. This work aims to reveal the relationship between the product morphology and sulfuric acid hydrolysis conditions (including acid concentration, temperature and time), and to realize morphological regulation of obtained NC. Three representative products were obtained from microcrystalline cellulose via sulfuric acid hydrolysis, which are cellulose nanocrystals with broad size distribution (W-CNC, 383.9 & PLUSMN; 131.7 nm in length, 6 & PLUSMN; 2.1 nm in height) obtained by 61 % H2SO4, 55 degrees C and 90 min, cellulose nanospheres (CNS, 61.3 & PLUSMN; 15.9 nm in diameter) obtained by 64 % H2SO4, 35 degrees C and 75 min, and CNC with narrow size distribution (N-CNC, 276.1 & PLUSMN; 28.7 nm in length, 4.1 & PLUSMN; 0.6 nm in height), obtained by 64 % H2SO4, 45 degrees C and 45 min. The results showed that the crystallographic form of W-CNC and N-CNC are cellulose I, while cellulose I and II coexist in CNS. Only W-CNC and N-CNC can form chiral nematic structures through evaporation-induced self-assembly strategy and reflected light with specific wavelengths. In addition, the formation mechanism of CNS with cellulose I/II was proposed, which provided a better understanding of NC morphology regulation.

Automated summary

This study aims to investigate the relationship between the morphology of nanocellulose and the sulfuric acid hydrolysis conditions, and to regulate the morphology of the obtained nanocellulose. Three representative products were obtained through sulfuric acid hydrolysis, with different sizes and crystallographic forms. The results showed that the morphology of nanocellulose can be controlled by adjusting the hydrolysis conditions.