From Fibrillar Networks to Functional Materials: Structure, Properties and Applications of Nanocellulose Networks

Publication date

2019-04-02

Authors

Mohan, S.ISNI 0000000524243805

Editors

Advisors

Supervisors

van Blaaderen, AlfonsISNI 0000000388251965
Velikov, K.ISNI 0000000395314696
Imhof, ArnoutISNI 0000000369252655

DOI

Document Type

Dissertation

License

Abstract

In this thesis, we focussed on unravelling the unique attributes of cellulose microfibril (CMF) networks using different experimental tools, in order to further the application potential of these sustainable material systems. As a first step, we quantified the 3D micro and nano-scale structure of CMF networks in situ using confocal microscopy and image analysis methods. The inter-fibrillar interactions between CMFs were quantified theoretically and experimental implementation of these findings resulted in significant changes in their network microstructure. From a rheological perspective, we showed that these networks undergo a transition with increasing shear stress from a predominantly elastic to a plastic deformation and are capable of quickly regaining their original viscoelastic moduli upon removal of the stress. We also studied the properties of a composite system obtained on combining CMFs with another commonly used bio-based polymer, agarose. The composite networks exhibited a synergistic enhancement in the stiffness depending on the ratio of its constituent networks. Finally, we provided a template for the fabrication of CMFs- based transparent functional films, which are potential alternatives for petroleum-based plastics in many applications.

Keywords

nanocellulose, material science, biopolymer, polymer networks, sustainable materials, rheology, films, gels

Citation

Mohan , S 2019, 'From Fibrillar Networks to Functional Materials: Structure, Properties and Applications of Nanocellulose Networks', Doctor of Philosophy, Universiteit Utrecht, [Utrecht].