# Nanocellulose Fragmentation Mechanisms and Inversion of Chirality from   the Single Particle to the Cholesteric Phase

**Authors:** Gustav Nystr\"om, Jozef Adamcik, Ivan Usov, Mario Arcari, Raffaele, Mezzenga

arXiv: 1705.06620 · 2017-05-19

## TL;DR

This study investigates how nanocellulose fibrils fragment and invert their chirality during self-assembly, revealing mechanisms that influence their structural and functional properties across different scales.

## Contribution

It provides new insights into the fragmentation processes and chirality inversion mechanisms of nanocellulose, combining microscopic and statistical analyses at multiple length scales.

## Key findings

- Fragmentation of nanocellulose fibrils is driven by mechanical and chemical factors.
- Chirality in nanocellulose inverts from right-handed at the fibril level to left-handed in the liquid crystal phase.
- Self-assembly leads to cholesteric liquid crystals with inverted chirality.

## Abstract

Understanding how nanostructure and nanomechanics influence physical material properties on the micro- and macroscale is an essential goal in soft condensed matter research. Mechanisms governing fragmentation and chirality inversion of filamentous colloids are of specific interest because of their critical role in load-bearing and self-organizing functionalities of soft nanomaterials. Here we provide a fundamental insight into the self-organization across several length scales of nanocellulose, an important bio-colloid system with wide-ranging applications as structural, insulating and functional material. Through a combined microscopic and statistical analysis of nanocellulose fibrils at the single particle level, we show how mechanically and chemically induced fragmentation proceed in this system. Moreover, by studying the bottom-up self-assembly of fragmented carboxylated cellulose nanofibrils into cholesteric liquid crystals, we show via direct microscopic observations, that the chirality is inverted from right-handed at the nanofibril level to left-handed at the level of the liquid crystal phase. These results improve our fundamental understanding of nanocellulose and provide an important rationale for their application in colloidal systems, liquid crystals and nanomaterials.

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Source: https://tomesphere.com/paper/1705.06620